Rigidity transition in polydisperse shear-thickening suspensions

Abstract

Shear thickening suspensions of non-Brownian polydisperse particles are simulated in 2D using a discrete element method based algorithm (LF-DEM) at high packing fractions (φ) and large non-dimensional stresses (σ). Rigidity analysis of the stress induced particle clusters is carried out using pebble game algorithm for polydisperse suspensions and compared with the statistically equivalent bidisperse systems. A critical value of the packing fraction, φc, close to the shear jamming transition, φJμ, (φc<φJμ) is obtained where rigid particle clusters begin to grow sharply. The growth is found to be characterized by a critical transition of an order parameter (frig), defined by the fraction of particles in rigid clusters which scales as, frig (φ-φc)β for φ>φc, and by the susceptibility scaling, rig|φ-φc |-γ, with exponents having values consistent with the critical exponents in 2D percolation transition. The variations of frig and rig in polydisperse suspensions are found to be identical to that of the statistically equivalent bidisperse suspensions. Finite size scaling analysis shows a divergence of correlation length near φc∞ following critical exponent ≈ 1.33, in agreement with the 2D percolation theory. Furthermore, φc and φJμ are found to vary non-monotonically with polydispersity index and depend on the particle stiffness.

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