A mathematical justification for nonlinear constitutive relations between stress and linearized strain

TL;DR

This paper introduces an asymptotic framework that rigorously derives nonlinear stress-strain relations in elastic bodies, expanding classical linear elasticity to include implicit, density-dependent, and non-quadratic constitutive models.

Contribution

It provides a rigorous mathematical justification for nonlinear constitutive relations between stress and linearized strain, extending classical models with implicit and more versatile relations.

Findings

Justifies nonlinear stress-strain relations including density-dependent moduli

Framework accommodates implicit constitutive relations

Includes relations derived from non-quadratic strain energies

Abstract

We present an asymptotic framework that rigorously generates nonlinear constitutive relations between stress and linearized strain for elastic bodies. Each of these relations arises as the leading order relationship satisfied by a one-parameter family of nonlinear constitutive relations between stress and nonlinear strain. The asymptotic parameter limits the overall range of strains that satisfy the corresponding constitutive relation in the one-parameter family while the stresses can remain large (relative to a fixed stress scale). This differs from classical linearized elasticity where a fixed constitutive relation is assumed, and the magnitude of the displacement gradient serves as the asymptotic parameter. Also unlike classical approaches, the constitutive relations in our framework are expressed as implicit relationships between stress and strain rather than requiring stress explicitly expressed as a function of strain, adding conceptual simplicity and versatility. We demonstrate that our framework rigorously justifies nonlinear constitutive relations between stress and linearized strain including those with density-dependent Young's moduli or derived from strain energies beyond quadratic forms.