Shear-stress fluctuations in self-assembled transient elastic networks

Abstract

Focusing on shear-stress fluctuations we investigate numerically a simple generic model for self-assembled transient networks formed by repulsive beads reversibly bridged by ideal springs. With dt being the sampling time and t*(f) 1/f the Maxwell relaxation time (set by the spring recombination frequency f) the dimensionless parameter x = dt/t*(f) is systematically scanned from the liquid limit ( dx 1) to the solid limit ( x 1) where the network topology is quenched and an ensemble average over m independent configurations is required. Generalizing previous work on permanent networks it is shown that the shear-stress relaxation modulus G(t) may be efficiently determined for all x using the simple-average expression G(t) = μA - h(t) with μA = G(0) characterizing the canonical-affine shear transformation of the system at t=0 and h(t) the (rescaled) mean-square displacement of the instantaneous shear stress as a function of time t. This relation is compared to the standard expression G(t) = C(t) using the (rescaled) shear-stress autocorrelation function C(t). Lower bounds for the m configurations required by both relations are given.