Geometry-dependent viscosity reduction in sheared active fluids
Abstract
We investigate flow pattern formation and viscosity reduction mechanisms in active fluids by studying a generalized Navier-Stokes model that captures the experimentally observed bulk vortex dynamics in microbial suspensions. We present exact analytical solutions including stress-free vortex lattices and introduce a computational framework that allows the efficient treatment of previously intractable higher-order shear boundary conditions. Large-scale parameter scans identify the conditions for spontaneous flow symmetry breaking, geometry-dependent viscosity reduction and negative-viscosity states amenable to energy harvesting in confined suspensions. The theory uses only generic assumptions about the symmetries and long-wavelength structure of active stress tensors, suggesting that inviscid phases may be achievable in a broad class of non-equilibrium fluids by tuning confinement geometry and pattern scale selection.
Cite
@article{arxiv.1608.01757,
title = {Geometry-dependent viscosity reduction in sheared active fluids},
author = {Jonasz Słomka and Jörn Dunkel},
journal= {arXiv preprint arXiv:1608.01757},
year = {2017}
}
Comments
supplementary movies available on request