Elasticity of Filamentous Kagome Lattice

Abstract

The diluted kagome lattice, in which bonds are randomly removed with probability 1-p, consists of straight lines that intersect at points with a maximum coordination number of four. If lines are treated as semi-flexible polymers and crossing points are treated as crosslinks, this lattice provides a simple model for two-dimensional filamentous networks. Lattice-based effective medium theories and numerical simulations for filaments modeled as elastic rods, with stretching modulus μ and bending modulus , are used to study the elasticity of this lattice as functions of p and . At p=1, elastic response is purely affine, and the macroscopic elastic modulus G is independent of . When = 0, the lattice undergoes a first-order rigidity percolation transition at p=1. When > 0, G decreases continuously as p decreases below one, reaching zero at a continuous rigidity percolation transition at p=pb ≈ 0.605 that is the same for all non-zero values of . The effective medium theories predict scaling forms for G, which exhibit crossover from bending dominated response at small /μ to stretching-dominated response at large /μ near both p=1 and p=pb, that match simulations with no adjustable parameters near p=1. The affine response as p→ 1 is identified with the approach to a state with sample-crossing straight filaments treated as elastic rods.