Fully-Mixed Virtual Element Method for the Biot Problem
Abstract
Poroelasticity describes the interaction of deformation and fluid flow in saturated porous media. A fully-mixed formulation of Biot's poroelasticity problem has the advantage of producing a better approximation of the Darcy velocity and stress field, as well as satisfying local mass and momentum conservation. In this work, we focus on a novel four-fields Virtual Element discretization of Biot's equations. The stress symmetry is strongly imposed in the definition of the discrete space, thus avoiding the use of an additional Lagrange multiplier. A complete a priori analysis is performed, showing the robustness of the proposed numerical method with respect to limiting material properties. The first order convergence of the lowest-order fully-discrete numerical method, which is obtained by coupling the spatial approximation with the backward Euler time-advancing scheme, is confirmed by a complete 3D numerical validation. A well known poroelasticity benchmark is also considered to assess the robustness properties and computational performance.
Cite
@article{arxiv.2504.17729,
title = {Fully-Mixed Virtual Element Method for the Biot Problem},
author = {Michele Botti and Daniele Prada and Anna Scotti and Michele Visinoni},
journal= {arXiv preprint arXiv:2504.17729},
year = {2025}
}