Evolving Microstructures in Relaxed Continuum Damage Mechanics for Strain Softening

TL;DR

This paper introduces a novel relaxation approach for modeling strain softening in continuum damage mechanics, ensuring mesh-independent simulations by convexifying the stress potential and allowing damage phases to elastically unload.

Contribution

It presents a new damage model that dynamically updates the convex hull of the stress potential, enabling realistic strain softening and mesh-independent results without extra parameters.

Findings

Model captures strain-softening behavior effectively.

Ensures mesh-independent structural simulations.

Applicable to fibrous biological tissues.

Abstract

A new relaxation approach is proposed which allows for the description of stress- and strain-softening at finite strains. The model is based on the construction of a convex hull replacing the originally non-convex incremental stress potential which in turn represents damage in terms of the classical $(1-D)$ approach. This convex hull is given as the linear convex combination of weakly and strongly damaged phases and thus, it represents the homogenization of a microstructure bifurcated in the two phases. As a result thereof, damage evolves in the convexified regime mainly by an increasing volume fraction of the strongly damaged phase. In contrast to previous relaxed incremental formulations in G\"urses and Miehe [16] and Balzani and Ortiz [2], where the convex hull has been kept fixated after construction, here, the strongly damaged phase is allowed to elastically unload upon further loading. At the same time, its volume fraction increases nonlinearly within the convexified regime. Thus, strain-softening in the sense of a decreasing stress with increasing strain can be modeled. The major advantage of the proposed approach is that it ensures mesh-independent structural simulations without the requirement of additional length-scale related parameters or nonlocal quantities, which simplifies an implementation using classical material subroutine interfaces. In this paper, focus is on the relaxation of one-dimensional models for fiber damage which are combined with a microsphere approach to allow for the description of three-dimensional fiber dispersions appearing in fibrous materials such as soft biological tissues. Several numerical examples are analyzed to show the overall response of the model and the mesh-independence of resulting structural calculations.