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KANG, IN SEOK (강인석)
Dept. of Chemical Engineering(화학공학과)
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FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant 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GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant 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GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant 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GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant 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GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant 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GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant 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GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant 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GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellipsoid:1||chaotic mixing:1||DEPOSITION:1||MONOPOLE EMISSION:1||DIFFUSER MODEL:1||crystalmelt interface shape:1||GADOLINIUM GALLIUM GARNET:1||INVERSION:1||drop deformation:1||Coulombic force:1||insulator:1||charged conducting droplet:1||CONTACTANGLE SATURATION:1||CONDUCTIVITY GRADIENTS:1||MASSSPECTROMETRY:1||DNA:1||droplet:1||DNAMOLECULES:1||DIELECTRIC SATURATION:1||PLATES:1||Endothelial cell:1||ELECTROROTATION:1||ANGLE:1||ROUGH:1||PATTERNS:1||the Czochralski method:1||CELL:1||bubble breakup:1||stability diagram:1||METAL MAGNETOHYDRODYNAMIC FLOW:1||creeping flow:1||movement:1||LOWREYNOLDSNUMBER:1||electrohydrodynamics (EHD):1||ELECTROSPRAY DEPOSITION:1||concentricdouble elastic inclusion:1||pulsatile flows:1||numerical solution:1||TENSION:1||WATER:1||labonachip:1||ELECTROOSMOTIC FLOW:1||eletroosmotic flow:1||numerical analysis:1||evaporation:1||FORCEFIELD:1||VISCOSITY:1||Electromagnetic stirring (EMS):1||BILLETS:1||CAVEOLIN1:1||SOLID PARTICLES:1||LIQUIDFLUID SYSTEMS:1||WETTING TENSION:1||PLASMA:1||czochralski method:1||single crystal growth:1||deformation:1||dielectric force:1||liquid bridge:1||FLUIDDYNAMICS:1||DNA MICROARRAY:1||MELT:1||charging:1||interface:1||PIV:1||ray tracing:1||DEPENDENCE:1||OPTIMIZATION:1||FLOW:8||DEFORMATION:8||DYNAMICS:7||SYSTEMS:7||electrohydrodynamics:7||FIELD:6||HEATTRANSFER:6||ENHANCEMENT:6||bubble departure volume:6||FREEBOUNDARY PROBLEMS:5||MODEL:5||CHIP:5||FILMS:4||COALESCENCE:3||CONVECTION:3||DIELECTROPHORESIS:3||NUMERICALSOLUTION:3||bubble:3||STABILITY:3||DROPLETS:3||FLUID:3||SILICON:3||variational method:3||SURFACES:3||DROPS:3||zeta potential:3||electroosmosis:3||ELECTROPHORESIS:3||optimization:3||PARTICLES:3||microchannel:3||CELLS:3||ELECTRICFIELDS:3||GEOMETRIES:3||TEMPERATURE:3||MICROFLUIDICS:3||BEHAVIOR:3||GROOVED CHANNELS:2||NAVIERSTOKES FLOWS:2||MICROMIXERS:2||LIQUID:2||MIXER:2||oscillation frequency:2||CAPILLARYELECTROPHORESIS:2||DIELECTRIC LIQUID:2||ELECTROHYDRODYNAMICS:2||Velocity:2||Transport:2||Acceleration:2||helical flow:2||ELECTROKINETIC INSTABILITY:2||MICROCHANNEL:2||minimal dispersion:2||TURNS:2||CARBON NANOTUBES:2||composite orthogonal coordinate system:2||microelectrode:2||micromixing:2||contact angle:2||electroosmotic flow:2||SEPARATIONS:2||POISSONBOLTZMANN EQUATION:2||LIQUIDDIELECTRIC LIQUID:2||MICROFLUIDIC DEVICES:2||CHEMISTRY:2||FIELDS:2||nonuniform electric field:2||microfluidics:2||BIOLOGY:2||ELECTROLYTE:2||PIPE:2||FORCES:2||INCOMPRESSIBLEFLOW:2||MICROCHIPS:2||SURFACETENSION:2||SIMULATION:2||Pneumatic:2||LEVITATED DROPS:2||HEATTRANSFER ENHANCEMENT:2||SUSPENSION:2||GROWTH:2||bubble oscillation:2||aspect ratio:2||CHANNELS:2||Solid:2||bubble shape:2||optimal boundary control:2||STRESS:2||CRYSTALGROWTH:2||electric field:2||BOUNDARY OPTIMALCONTROL:2||bubble on a tip:2||FREEENERGY:1||ACTUATION:1||Magnetohydrodynamics (MHD):1||Nonlinear dynamics:1||MOLD:1||SUBCELLULAR ORGANELLES:1||electric potential:1||MORPHOLOGY:1||FLOWS:1||FURROWED CHANNELS:1||singlecrystal growth:1||welldefined flows:1||KINETICS:1||point defects:1||microarrays:1||DIAGNOSTICS:1||BLOOD:1||Droplet dispensing:1||dielectric fluid:1||electrokinetics:1||INTERFACIALTENSION:1||MOLECULARDYNAMICS SIMULATIONS:1||FLUIDFLOW:1||DELIVERY:1||DESIGN:1||DIFFUSION:1||CHARGED DROPLET:1||ELECTROLYTIC SOLUTIONS:1||analytic solution:1||nonaxisymmetric electric field:1||leaky dielectric model:1||DOUBLELAYER:1||THERMODYNAMICS:1||AQUEOUSELECTROLYTE:1||MODES:1||SOLIDIFICATION:1||ADHESION:1||oxide single crystal:1||legendre polynomial:1||OSCILLATION:1||AC electric field:1||CHIPS:1||Electric induction:1||Electrostatic force:1||CAPILLARY RISE:1||TECHNOLOGY:1||VOLTAGE:1||MIXTURES:1||DROPLET:1||Industrial modeling:1||NATURALCONVECTION:1||MANIPULATION:1||Minimum drag force:1||STEADY:1||OSCILLATORY FLOW:1||optimization of the crystal surface temperatures thermal stress:1||numerical solutions:1||shape evolution:1||MELTGROWTH:1||MOTION:1||bubble deformation:1||uniaxial flow:1||Czochralski process:1||detergent:1||electrophoresis:1||electrowetting:1||control of spot size and dispensing volume:1||CRAZE INITIATION:1||instability:1||PROTEINS:1||PRESSURE:1||DEVICES:1||DIELECTROPHORETIC PLATFORMS:1||AC:1||ANALYSIS SYSTEMS:1||fuel cell:1||liquid junction:1||diffusion:1||CHARGE SEPARATION:1||drop:1||dielectrophoretic velocity:1||CONTACT ANGLES:1||ELECTROLYTESOLUTIONS:1||variational methods:1||INDUCED MORPHOLOGICAL INSTABILITIES:1||ENERGY:1||CONTACTANGLE:1||CZOCHRALSKIGROWN SILICON:1||STACKINGFAULT RING:1||liquid metalgas flow:1||electric charge:1||charged conducting drop:1||resonant frequency:1||ELECTRICFIELD:1||Capillary rise:1||Liquid bridge:1||FABRICATION:1||OXYGENTRANSPORT:1||coulombic force:1||Stokes equation:1||stenosed blood vessel:1||ELECTROPHORETIC SEPARATION:1||SEPARATION:1||GEOMETRY:1||FINITEELEMENTANALYSIS:1||channel flow:1||SOUND:1||coupled partial differential equations:1||DENDRITIC GROWTH:1||surface temperature distribution:1||magnetic field:1||FLUIDMECHANICS:1||GASBUBBLES:1||EHD method:1||MICROARRAYS:1||toughness of composite material:1||GLASSYPOLYMERS:1||CHARGE:1||SURFACE CONDUCTANCE:1||CONTACT LINE DEPOSITS:1||fluid flow velocity:1||CARBON:1||ELECTROWETTINGBASED ACTUATION:1||LATEST DEVELOPMENTS:1||Semiellip
