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Main Authors: Farrell, Patrick E., Mitchell, Lawrence, Scott, L. Ridgway
Format: Preprint
Published: 2022
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Online Access:https://arxiv.org/abs/2211.05494
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author Farrell, Patrick E.
Mitchell, Lawrence
Scott, L. Ridgway
author_facet Farrell, Patrick E.
Mitchell, Lawrence
Scott, L. Ridgway
contents In recent years a great deal of attention has been paid to discretizations of the incompressible Stokes equations that exactly preserve the incompressibility constraint. These are of substantial interest because these discretizations are pressure-robust, i.e. the error estimates for the velocity do not depend on the error in the pressure. Similar considerations arise in nearly incompressible linear elastic solids. Conforming discretizations with this property are now well understood in two dimensions, but remain poorly understood in three dimensions. In this work we state two conjectures on this subject. The first is that the Scott-Vogelius element pair is inf-sup stable on uniform meshes for velocity degree $k \ge 4$; the best result available in the literature is for $k \ge 6$. The second is that there exists a stable space decomposition of the kernel of the divergence for $k \ge 5$. We present numerical evidence supporting our conjectures.
format Preprint
id arxiv_https___arxiv_org_abs_2211_05494
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle Two conjectures on the Stokes complex in three dimensions on Freudenthal meshes
Farrell, Patrick E.
Mitchell, Lawrence
Scott, L. Ridgway
Numerical Analysis
In recent years a great deal of attention has been paid to discretizations of the incompressible Stokes equations that exactly preserve the incompressibility constraint. These are of substantial interest because these discretizations are pressure-robust, i.e. the error estimates for the velocity do not depend on the error in the pressure. Similar considerations arise in nearly incompressible linear elastic solids. Conforming discretizations with this property are now well understood in two dimensions, but remain poorly understood in three dimensions. In this work we state two conjectures on this subject. The first is that the Scott-Vogelius element pair is inf-sup stable on uniform meshes for velocity degree $k \ge 4$; the best result available in the literature is for $k \ge 6$. The second is that there exists a stable space decomposition of the kernel of the divergence for $k \ge 5$. We present numerical evidence supporting our conjectures.
title Two conjectures on the Stokes complex in three dimensions on Freudenthal meshes
topic Numerical Analysis
url https://arxiv.org/abs/2211.05494