Random and Correlated Roughening in Slow Fracture by Damage Nucleation

TL;DR

This paper investigates how different types of material disorder influence crack roughness during slow fracture, revealing distinct roughening behaviors depending on whether disorder is quenched or annealed.

Contribution

It introduces two models with different disorder types, demonstrating how quenched and annealed disorders lead to different crack roughness exponents in 2D.

Findings

Quenched disorder yields roughness exponent ~0.5.

Annealed disorder yields roughness exponent ~0.66.

Different disorder types cause qualitatively different crack roughening.

Abstract

We address the role of the nature of material disorder in determining the roughness of cracks which grow by damage nucleation and coalescence ahead of the crack tip. We highlight the role of quenched and annealed disorders in relation to the length scales $d$ and $\xi_c$ associated with the disorder and the damage nucleation respectively. In two related models, one with quenched disorder in which $d \simeq \xi_c $, the other with annealed disorder in which $d \ll \xi_c$, we find qualitatively different roughening properties for the resulting cracks in 2-dimensions. The first model results in random cracks with an asymptotic roughening exponent $\zeta \approx 0.5$. The second model shows correlated roughening with $\zeta\approx 0.66$. The reasons for the qualitative difference are rationalized and explained.