A smoothed particle hydrodynamics approach for phase field modeling of brittle fracture

TL;DR

This paper introduces a novel phase field model for brittle fracture within the meshfree Smoothed Particle Hydrodynamics (SPH) framework, enabling accurate simulation of complex crack behaviors without prior crack path knowledge.

Contribution

It develops and implements a phase field approach for brittle fracture in SPH, addressing limitations of previous empirical damage models and enhancing simulation capabilities.

Findings

Successfully models complex crack initiation and propagation

Demonstrates accuracy and efficiency in numerical examples

Provides detailed mathematical and implementation framework

Abstract

Fracture is a very challenging and complicated problem with various applications in engineering and physics. Although it has been extensively studied within the context of mesh-based numerical techniques, such as the finite element method (FEM), the research activity within the Smoothed Particle Hydrodynamics (SPH) community remains scarce. SPH is a particle-based numerical method used to discretize equations of continuum media. Its meshfree nature makes it ideal to simulate fracture scenarios that involve extreme deformations. However, to model fracture, SPH researchers have mostly relied on ad-hoc empirical local damage models, cohesive zone approaches, or pseudo-spring models, which come with a set of drawbacks and limitations. On the other hand, phase field models of brittle fracture have recently gained popularity in academic circles and provide significant improvements compared to previous approaches. These improvements include the derivation from fundamental fracture theories, the introduction of non-locality, and the ability to model multiple crack initiation, propagation, branching, and coalescence, in situations where no prior knowledge of the crack paths is available. Nevertheless, phase field for fracture has not been studied within SPH. In this proof-of-concept paper we develop and implement a phase field model of brittle fracture within the context of SPH. Comprehensive mathematical and implementation details are provided, and several challenging numerical examples are computed and illustrate the proposed method's ability to accurately and efficiently simulate complex fracture scenarios.