Finite element approximation of steady flows of incompressible fluids with implicit power-law-like rheology
Provides a rigorous convergence analysis for finite element methods applied to a broad class of non-Newtonian fluid models, addressing a gap in numerical analysis for implicit constitutive laws.
The paper develops a finite element approximation for implicit power-law-like fluid models with maximal monotone r-graphs, proving convergence of a subsequence of finite element solutions to a weak solution as mesh size tends to zero.
We develop the analysis of finite element approximations of implicit power-law-like models for viscous incompressible fluids. The Cauchy stress and the symmetric part of the velocity gradient in the class of models under consideration are related by a, possibly multi--valued, maximal monotone $r$-graph, with $1<r<\infty$. Using a variety of weak compactness techniques, including Chacon's biting lemma and Young measures, we show that a subsequence of the sequence of finite element solutions converges to a weak solution of the problem as the finite element discretization parameter $h$ tends to 0. A key new technical tool in our analysis is a finite element counterpart of the Acerbi--Fusco Lipschitz truncation of Sobolev functions.