Microscopic mechanics of fiber networks
- 1 March 1994
- journal article
- research article
- Published by AIP Publishing in Journal of Applied Physics
- Vol. 75 (5) , 2383-2392
- https://doi.org/10.1063/1.356259
Abstract
We report simulations of two‐dimensional fiber networks of random geometry. The stress distribution along a fiber agrees with the mean‐field Cox prediction, but the stress transfer factor is determined by the properties of the whole fiber and not by just the local segment stiffness as suggested by micromechanical models. This leads to a linear density dependence of the Young’s modulus of a network. The initial loss of stiffness at small strain can be explained with an exponential frequency distribution of microscopic stresses, and the asymptotic stiffness at large external strain agrees with mean‐field predictions. The simulated behavior is independent of the microscopic fracture mechanism in both regions.This publication has 20 references indexed in Scilit:
- Symmetry-Breaking Fracture in Random Fibre NetworksEurophysics Letters, 1993
- Scale-invariant disorder in fracture and related breakdown phenomenaPhysical Review B, 1991
- Fracture of disordered, elastic lattices in two dimensionsPhysical Review B, 1989
- Computer Simulation of the Uniaxial Elastic-Plastic Behavior of PaperJournal of Engineering Materials and Technology, 1988
- Elastic fracture in random materialsPhysical Review B, 1988
- Size and location of the largest current in a random resistor networkPhysical Review B, 1987
- Breakdown properties of quenched random systems: The random-fuse networkPhysical Review B, 1987
- Elastic percolation models for cohesive mechanical failure in heterogeneous systemsPhysical Review B, 1986
- A random fuse model for breaking processesJournal de Physique Lettres, 1985
- Percolation and conductivity: A computer study. IPhysical Review B, 1974