Title :
Spatially controlled microfluidics using low-voltage electrokinetics
Author :
Guzmán, Katherine A Dunphy ; Karnik, Rohit N. ; Newman, John S. ; Majumdar, Arun
Author_Institution :
Mech. Eng. Dept., Univ. of California, Berkeley, USA
Abstract :
Most electrokinetic microfluidic devices currently require high voltages (>50 V) to generate sustained electric fields. However, two long-standing limitations remain, namely: (i) the resulting electrolysis of water produces bubbles, forcing electrodes to be placed in reservoirs outside the channels, and (ii) direct integration with low-voltage microelectronics cannot be achieved. A further limitation is the lack of spatial control within the microchannel. This work presents a method to achieve low-voltage (≤1 V) electrokinetic transport using micropatterned Ag-AgCl electrode arrays, which allows spatial flow control within microchannels. We demonstrate bidirectional electrophoretic control of microparticles within microfluidic channels using ±1 V.
Keywords :
electrokinetic effects; flow control; microchannel flow; silver; silver compounds; 1 V; Ag-AgCl; electrokinetic microfluidic devices; electrokinetic transport; electrophoretic control; low-voltage electrokinetics; microchannels flow; microfluidic channels; micropatterned electrode arrays; spatial flow control; spatially controlled microfluidics; sustained electric fields; Electrochemical processes; Electrodes; Electrokinetics; Fluid flow control; Mechanical engineering; Microchannel; Microelectronics; Microfluidics; Reservoirs; Voltage; Ag-AgCl electrodes; electrokinetics; low voltage; microchannels; microfluidics;
Journal_Title :
Microelectromechanical Systems, Journal of
DOI :
10.1109/JMEMS.2005.863789
