In this article we introduce a novel coupled algorithm for massively parallel direct numerical simulations of electrophoresis in microfluidic flows. This multiphysics algorithm employs an Eulerian description of fluid and ions, combined with a Lagrangian representation of moving charged particles. The fixed grid facilitates efficient solvers and the employed lattice Boltzmann method can efficiently handle complex geometries. Validation experiments with more than 70000 time steps are presented, together with scaling experiments with over 4⋅106 particles and 1.96⋅1011 grid cells for both hydrodynamics and electric potential. We achieve excellent performance and scaling on up to 65536 cores of a current supercomputer.
@article{arxiv.1708.08741,
title = {A Scalable Multiphysics Algorithm for Massively Parallel Direct Numerical Simulations of Electrophoresis},
author = {Dominik Bartuschat and Ulrich Rüde},
journal= {arXiv preprint arXiv:1708.08741},
year = {2018}
}
Comments
Accepted manuscript of publication in Journal of Computational Science (Elsevier)