Title :
Meshless analysis of steady-state electro-osmotic transport
Author :
Mitchell, M.J. ; Qiao, R. ; Aluru, N.R.
Author_Institution :
Dept. of Electr. & Comput. Eng., Illinois Univ., Urbana, IL, USA
Abstract :
An emerging technology in the area of microsystems is micro-total analysis systems (/spl mu/TAS) for biological sample analysis. We have simulated electro-osmosis-a common transport mechanism within these devices-by developing meshless techniques. Numerical simulation of electro-osmotic transport requires the solution of the Laplace equation, the Poisson-Boltzmann equation and the incompressible Stokes or Navier-Stokes equations. We describe the development and implementation of meshless techniques for all the governing equations. In particular we introduce a stabilized Stokes solver for very-low Reynolds number flows and a multistep Navier-Stokes solver for a wide range of Reynolds number flows. We have analyzed electro-osmotic transport in three geometries typically encountered in biological devices: a straight channel, a cross-shaped intersection, and a T-shaped intersection.
Keywords :
Laplace equations; Navier-Stokes equations; Poisson equation; bioelectric phenomena; biological fluid dynamics; biological techniques; electrokinetic effects; electrophoresis; interpolation; microfluidics; osmosis; Laplace equation; Poisson-Boltzmann equation; T-shaped intersection; biological sample analysis; cross-shaped intersection; governing equations; incompressible Navier-Stokes equation; incompressible Stokes equation; meshless analysis; micro-total analysis systems; multistep Navier-Stokes solver; stabilized Stokes solver; steady-state electro-osmotic transport; straight channel; very-low Reynolds number flows; Clouds; Design automation; Electro-osmosis; Fluid flow control; Laplace equations; Mesh generation; Micromechanical devices; Poisson equations; Solid modeling; Steady-state;
Journal_Title :
Microelectromechanical Systems, Journal of
