Growth, Percolation, and Correlations in Disordered Fiber Networks

Abstract

This paper studies growth, percolation, and correlations in disordered fiber networks. We start by introducing a 2D continuum deposition model with effective fiber-fiber interactions represented by a parameter p which controls the degree of clustering. For p=1, the deposited network is uniformly random, while for p=0 only a single connected cluster can grow. For p=0, we first derive the growth law for the average size of the cluster as well as a formula for its mass density profile. For p>0, we carry out extensive simulations on fibers, and also needles and disks to study the dependence of the percolation threshold on p. We also derive a mean-field theory for the threshold near p=0 and p=1 and find good qualitative agreement with the simulations. The fiber networks produced by the model display nontrivial density correlations for p<1. We study these by deriving an approximate expression for the pair distribution function of the model that reduces to the exactly known case of a uniformly random network. We also show that the two-point mass density correlation function of the model has a nontrivial form, and discuss our results in view of recent experimental data on mass density correlations in paper sheets.

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