A mixed variational principle in nonlinear elasticity using Cartan's moving frame and implementation with finite element exterior calculus

TL;DR

This paper introduces a novel mixed variational principle for nonlinear elasticity using Cartan's moving frame and finite element exterior calculus, enabling stable and accurate numerical solutions without additional stabilization.

Contribution

It develops a new geometric framework for nonlinear elasticity based on differential forms and Cartan's moving frame, combined with a finite element exterior calculus implementation.

Findings

Discretization avoids locking and convergence issues.

Numerical experiments demonstrate stability and accuracy.

Framework generalizes to 2D nonlinear elasticity problems.

Abstract

This article offers a new perspective for the mechanics of solids using moving Cartan's frame, specifically discussing a mixed variational principle in non-linear elasticity. We treat quantities defined on the co-tangent bundles of reference and deformed configurations as additional unknowns. Such a treatment invites compatibility of the fields with base-space (configurations of the body), so that the configuration can be realised as a subset of the Euclidean space. We first rewrite the metric and connection using differential forms, which are further utilised to write the deformation gradient and Cauchy-Green deformation tensor in terms of frame and co-frame fields. The geometric understanding of stress as a co-vector valued 2-form fits squarely within our overall program. We show that, for a hyperelastic solid, an equation similar to the Doyle-Erciksen formula may be written for the co-vector part of stress. Using these, we write a mixed energy functional in terms of differential forms, whose extremum leads to the compatibility of deformation, constitutive rules and equations of equilibrium. Finite element exterior calculus is then utilised to construct a finite dimensional approximation for the differential forms appearing in the variational principle. These approximations are then used to construct a discrete functional which is then numerically extremised. This discertization leads to a mixed method as it uses independent approximations for differential forms related to stress and deformation gradient. The mixed variational principle is then specialized for 2D case, whose discrete approximation is applied to problems in nonlinear elasticity. An important feature of our FE technique is the lack of additional stabilization. From the numerical study, it is found that the present discretization also does not suffer form locking and related convergence issues.