Pulsatile Flows for Simplified Smart Fluids with Variable Power-Law: Analysis and Numerics
Abstract
We study the fully-developed, time-periodic motion of a shear-dependent non-Newtonian fluid with variable exponent rheology through an infinite pipe , , of arbitrary cross-section . The focus is on a generalized -fluid model, where the power-law index is position-dependent (with respect to ), , a function . We prove the existence of time-periodic solutions with either assigned time-periodic flow-rate or pressure-drop, generalizing known results for the Navier-Stokes and for -fluid equations. In addition, we identify explicit solutions, relevant as benchmark cases, especially for electro-rheological fluids or, more generally, . To support practical applications, we present a fully-constructive existence proof for variational solutions by means of a fully-discrete finite-differences/-elements discretization, consistent with our numerical experiments. Our approach, which unifies the treatment of all values of , , without requiring an auxiliary Newtonian term, provides new insights even in the constant exponent case. The theoretical findings are reviewed by means of numerical experiments.
Cite
@article{arxiv.2507.22449,
title = {Pulsatile Flows for Simplified Smart Fluids with Variable Power-Law: Analysis and Numerics},
author = {Luigi C. Berselli and Alex Kaltenbach},
journal= {arXiv preprint arXiv:2507.22449},
year = {2025}
}
Comments
37 pages, 12 figures