Physics and chemistry-based constitutive framework for thermo-chemically aged elastomer using phase-field approach

TL;DR

This paper introduces a physics and chemistry-based constitutive model for thermo-chemically aged elastomers, incorporating phase-field fracture to predict stress responses and brittle failure, validated against experimental data.

Contribution

It develops a self-contained framework that links chemical aging processes to mechanical behavior using only four material properties, implemented in finite element analysis.

Findings

The model accurately predicts the mechanical response of aged elastomers.

Chemical crosslinking causes stiffening and brittle behavior in aged elastomers.

Numerical simulations show the impact of evolving properties on crack-containing specimens.

Abstract

We propose a physics and chemistry-based constitutive framework to predict the stress responses of thermo-chemically aged elastomers and capture their brittle failure using the phase-field approach. High-temperature aging in the presence of oxygen causes the macromolecular network of elastomers to undergo complex chemical reactions inducing two main mechanisms: chain-scission and crosslinking. Chemical crosslinking contributes to the stiffening behavior characterizing the brittle response of aged elastomers. In this work, we first modify the Helmholtz free energy to incorporate the effect of thermo-chemically-driven crosslinking processes. Then, we equip the constitutive description with phase-field to capture the induced brittle failure via a strain-based criterion for fracture. We show that our proposed framework is self-contained and requires only four main material properties whose evolution due to thermo-chemical aging is characterized entirely by the change of the crosslink density obtained based on chemical characterization experiments. The developed constitutive framework is first solved analytically for the case of uniaxial tension in a homogeneous bar to highlight the interconnection between all four material properties. Then, the framework is numerically implemented within a finite element (FE) context via a user-element subroutine (UEL) in the commercial FE software Abaqus to simulate more complicated geometries and loading states. The framework is finally validated with respect to a set of experimental results available in the literature. The comparison confirms that the proposed constitutive framework can accurately predict the mechanical response of thermo-chemically aged elastomers. Further numerical examples are provided to demonstrate the effects of evolving material properties on the response of specimens containing pre-existing cracks.