Frictional contact between solids: A fully Eulerian phase-field approach

TL;DR

This paper introduces a fully Eulerian phase-field method for modeling frictional contact between deformable solids, enabling efficient simulation of large sliding, stick-slip transitions, and energy dissipation.

Contribution

It extends previous Eulerian contact models to include frictional interactions using phase fields and penalty forces, allowing independent body motion and accurate contact behavior.

Findings

Handles large sliding motions effectively

Captures stick-slip transition accurately

Preserves history-dependent energy dissipation

Abstract

Recent advancements have demonstrated that fully Eulerian methods can effectively model frictionless contact between deformable solids. Unlike traditional Lagrangian approaches, which require contact detection and resolution algorithms, the Eulerian framework utilizes a single, fixed spatial mesh combined with a diffuse interface phase-field approach, simplifying contact resolution significantly. Moreover, the Eulerian method is well-suited for developing a unified framework to handle multiphysical systems involving growing bodies that interact with a constraining medium. In this work, we extend our previous methodology to incorporate frictional contact. By leveraging the intersection of the phase fields of multiple bodies, we define normal and tangential penalty force fields, which are incorporated into the linear momentum equations to capture frictional interactions. This formulation allows independent motion of each body using distinct velocity fields, coupled solely through interfacial forces arising from contact and friction. We thoroughly validate the proposed approach through several numerical examples. The method is shown to handle large sliding effortlessly, accurately capture the stick-slip transition, and preserve history-dependent energy dissipation, offering a solution for modeling frictional contact in Eulerian models.