Shape transitions in a soft incompressible sphere with residual stresses

TL;DR

This study investigates how residual stresses influence the shape stability of incompressible soft spheres, combining linear stability analysis and finite element simulations to understand morphological transitions and potential applications in tissue characterization.

Contribution

It introduces an alternative strain energy approach to model residual stresses and analyzes their impact on sphere stability and morphology, providing new insights into soft tissue mechanics.

Findings

Residual stresses induce shape transitions in soft spheres.

Maximum compressive hoop residual stress triggers morphological changes.

Results suggest methods for nondestructive residual stress measurement in tissues.

Abstract

Residual stresses may appear in elastic bodies due to the formation of misfits in the micro-structure, driven by plastic deformations, thermal or growth processes. They are especially widespread in living matter, resulting from the dynamic remodelling processes aiming at optimizing the overall structural response to environmental physical forces. From a mechanical viewpoint, residual stresses are classically modelled through the introduction of a virtual incompatible state that collects the local relaxed states around each material point. In this work, we instead employ an alternative approach based on a strain energy function that constitutively depends only on the deformation gradient and the residual stress tensor. In particular, our objective is to study the morphological stability of an incompressible sphere, made of a neo-Hookean material and subjected to given distributions of residual stresses. Firstly, we perform a linear stability analysis on the pre-stressed solid sphere using the method of incremental deformations. The marginal stability conditions are given as a function of a control parameter, being the dimensionless variable that represents the characteristic intensity of the residual stresses. Secondly, we perform finite element simulations using a mixed formulation in order to investigate the post-buckling morphology in the fully nonlinear regime. Considering different distributions of the residual stresses, we find that different morphological transitions occur around the material domain where the hoop residual stress reaches its maximum compressive value. The results provide useful guidelines in order to design morphable soft spheres, for example by controlling the residual stresses through active deformations. They finally suggest a viable solution for the nondestructive characterization of residual stresses in soft tissues, such as solid tumors.