A unified sharp-diffusive phase-field model for bulk and interfacial cohesive fracture

TL;DR

This paper introduces a unified phase-field model that accurately captures both bulk and interfacial cohesive fractures by incorporating a localized interfacial source term, enabling independent control of interface toughness.

Contribution

The proposed model leverages the $oldsymbol{ ext{ extOmega}}^2$-model to naturally produce sharp discontinuities and unify the description of bulk and interfacial fracture using a single parametric framework.

Findings

Model accurately reproduces diverse interfacial cohesive laws.

Captures competition between interfacial debonding and matrix cracking.

Validated through numerical benchmarks.

Abstract

In traditional phase-field modeling of multiphase materials, a significant challenge arises from the non-local nature of fracture energy regularization, where interfacial toughness is inherently coupled with the properties of the surrounding bulk phases. Achieving consistency with prescribed material properties typically necessitates complex corrections and exceptionally fine local mesh refinement near the interfaces. To address this fundamental issue, we leverage the capacity of the recently proposed $\Omega^2$-model to manifest Dirac-like damage concentration and emergent displacement discontinuities, while introducing an analytical, strongly localized interfacial source term $q_{\phi}$ into the phase-field formulation. It should be emphasized that the ``sharp" nature of the proposed model manifests as a naturally emergent strong discontinuity within a continuum framework, fundamentally distinguishing it from inherently discrete approaches such as cohesive element method. This allows for the independent and precise control of interface toughness in a straightforward manner. Theoretical analysis further reveals that the proposed framework can describe the cohesive failure of both bulk and interfacial regions using a unified set of parametric equations for the cohesive law, where the model parameters are directly determined by the local material properties without the need for additional corrections. The model's versatility is numerically validated through a series of benchmarks. The results confirm that the proposed model not only accurately reproduces diverse interfacial cohesive laws but also captures the intricate competition between interfacial debonding and matrix cracking. This sharp-diffusive phase-field model may provide a robust and computationally efficient tool for predicting complex fracture trajectories in sophisticated engineering materials.