We present a novel, low voltage particle mixing and concentration paradigm that exploits the interplay between electrokinetic, dielectrophoretic, and pressure-driven flows. Applying electrokinetic and pressure-driven forces of similar magnitudes in opposite directions largely cancels these two forces and results in the smaller dielectrophoretic force becoming significant. The sum of these three forces throughout the microchannel results in particle concentration and mixing regions. The devices presented utilize weak DC fields (5-25 V/cm) and patterned, insulating microfluidic channels. This approach has been applied to latex beads varying in size by two orders of magnitude (2 μm - 20 nm) using one channel geometry and has been applied to bo...
This paper presents a novel dielectrophoresis (DEP)-based microfluidic device which combines round h...
Controlled manipulation of synthetic particles and biological cells from a complex mixture is import...
We describe a novel particle separation technique that combines deterministic lateral displacement (...
The objective of this research is to study the enhancement of the mixing effect and the manipulation...
Microfluidic systems offer integration of multiple functions on a single platform. Automated or remo...
This article describes the engineering development of a continuous-flow, selective particle filter/c...
This thesis research aims at advancing our understanding of the coupled electric and hydrodynamic pr...
Microfluidic platforms capable of complex on-chip processing and liquid handling enable a wide varie...
Microfluidic devices can make a significant impact in many fields where obtaining a rapid response i...
A new microfluidic approach for charge-based particle separation using combined hydrodynamic and ele...
Lab-on-Chip systems integrate multiple functionalities on a single platform. Automated or remote man...
Electrokinetics plays an important role in facilitating fluid transport and particle manipulation in...
Electrokinetic manipulation refers to the control of particle and cell motions using an electric fie...
Microfluidic manipulation of particulate matters has found its applications in cell handling, virus ...
This paper presents a novel dielectrophoresis-based microfluidic device incorporating round hurdles ...
This paper presents a novel dielectrophoresis (DEP)-based microfluidic device which combines round h...
Controlled manipulation of synthetic particles and biological cells from a complex mixture is import...
We describe a novel particle separation technique that combines deterministic lateral displacement (...
The objective of this research is to study the enhancement of the mixing effect and the manipulation...
Microfluidic systems offer integration of multiple functions on a single platform. Automated or remo...
This article describes the engineering development of a continuous-flow, selective particle filter/c...
This thesis research aims at advancing our understanding of the coupled electric and hydrodynamic pr...
Microfluidic platforms capable of complex on-chip processing and liquid handling enable a wide varie...
Microfluidic devices can make a significant impact in many fields where obtaining a rapid response i...
A new microfluidic approach for charge-based particle separation using combined hydrodynamic and ele...
Lab-on-Chip systems integrate multiple functionalities on a single platform. Automated or remote man...
Electrokinetics plays an important role in facilitating fluid transport and particle manipulation in...
Electrokinetic manipulation refers to the control of particle and cell motions using an electric fie...
Microfluidic manipulation of particulate matters has found its applications in cell handling, virus ...
This paper presents a novel dielectrophoresis-based microfluidic device incorporating round hurdles ...
This paper presents a novel dielectrophoresis (DEP)-based microfluidic device which combines round h...
Controlled manipulation of synthetic particles and biological cells from a complex mixture is import...
We describe a novel particle separation technique that combines deterministic lateral displacement (...
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