English

Boundary elements method for microfluidic two-phase flows in shallow channels

Fluid Dynamics 2014-12-09 v1

Abstract

In the following work we apply the boundary element method to two-phase flows in shallow microchannels, where one phase is dispersed and does not wet the channel walls. These kinds of flows are often encountered in microfluidic Lab-on-a-Chip devices and characterized by low Reynolds and low capillary numbers. Assuming that these channels are homogeneous in height and have a large aspect ratio, we use depth-averaged equations to describe these two-phase flows using the Brinkman equation, which constitutes a refinement of Darcy's law. These partial differential equations are discretized and solved numerically using the boundary element method, where a stabilization scheme is applied to the surface tension terms, allowing for a less restrictive time step at low capillary numbers. The convergence of the numerical algorithm is checked against a static analytical solution and on a dynamic test case. Finally the algorithm is applied to the non-linear development of the Saffman-Taylor instability and compared to experimental studies of droplet deformation in expanding flows.

Keywords

Cite

@article{arxiv.1411.2728,
  title  = {Boundary elements method for microfluidic two-phase flows in shallow channels},
  author = {Mathias Nagel and François Gallaire},
  journal= {arXiv preprint arXiv:1411.2728},
  year   = {2014}
}

Comments

accepted for publication, Computers and Fluids 2014

R2 v1 2026-06-22T06:54:24.889Z