Scaling Laws for Fracture of Heterogeneous Materials and Rock

21 October 1996

journal article
research article
Published by American Physical Society (APS) in Physical Review Letters

Vol. 77 (17) , 3689-3692
https://doi.org/10.1103/physrevlett.77.3689

Abstract

Using computer simulation we show that, near the global failure point, the cumulative elastic energy released during fracturing of heterogeneous solids follows a power law with log-periodic corrections to the leading term. This is consistent with a recently proposed scaling law that relates the dynamics of the precursors of large earthquakes to their occurrence time, thus providing a rational basis for it in terms of rupture of the rock. It is also consistent with the scaling of acoustic emissions that precede fracture of composite materials, with the time to failure, and may thus provide a basis for predicting fracture of materials.

Keywords

This publication has 18 references indexed in Scilit:

Stock Market Crashes, Precursors and Replicas
Journal de Physique I, 1996
Introduction of scaling techniques in brittle fracture of rocks
Physics of the Earth and Planetary Interiors, 1994
Statistical physics of fault patterns self-organized by repeated earthquakes
Pure and Applied Geophysics, 1994
Seismicity trends and potential for large earthquakes in the Alaska-Aleutian region
Pure and Applied Geophysics, 1994
Predictive modeling of the seismic cycle of the Greater San Francisco Bay Region
Journal of Geophysical Research, 1993
Mechanics of disordered solids. III. Fracture properties
Physical Review B, 1993
Percolation and fracture in disordered solids and granular media: Approach to a fixed point
Physical Review Letters, 1992
Earthquake rupture as a critical point: consequences for telluric precursors
Tectonophysics, 1990
Test of universality for three-dimensional models of mechanical breakdown in disordered solids
Physical Review B, 1990
Elastic percolation models for cohesive mechanical failure in heterogeneous systems
Physical Review B, 1986