Statistical Models of Fracture

TL;DR

This paper reviews lattice models of fracture that incorporate disorder and long-range interactions, connecting statistical physics theories with traditional fracture mechanics to understand material failure and crack phenomena.

Contribution

It provides a comprehensive overview of recent advances in lattice fracture models, emphasizing their relation to statistical physics and experimental observations.

Findings

Scaling and size effects in material strength analyzed

Statistics of avalanches and microfailures discussed

Crack surface morphology characterized as self-affine fractals

Abstract

Disorder and long-range interactions are two of the key components that make material failure an interesting playfield for the application of statistical mechanics. The cornerstone in this respect has been lattice models of the fracture in which a network of elastic beams, bonds or electrical fuses with random failure thresholds are subject to an increasing external load. These models describe on a qualitative level the failure processes of real, brittle or quasi-brittle materials. This has been particularly important in solving the classical engineering problems of material strength: the size dependence of maximum stress and its sample to sample statistical fluctuations. At the same time, lattice models pose many new fundamental questions in statistical physics, such as the relation between fracture and phase transitions. Experimental results point out to the existence of an intriguing crackling noise in the acoustic emission and of self-affine fractals in the crack surface morphology. Recent advances in computer power have enabled considerable progress in the understanding of such models. Among these partly still controversial issues, are the scaling and size effects in material strength and accumulated damage, the statistics of avalanches or bursts of microfailures, and the morphology of the crack surface. Here we present an overview of the results obtained with lattice models for fracture, highlighting the relations with statistical physics theories and more conventional fracture mechanics approaches.