Rigid clusters in shear-thickening suspensions: a nonequilibrium critical transition

Abstract

The onset and growth of rigid clusters in a two-dimensional (2D) suspension in shear flow are studied by numerical simulations. The suspension exhibits the lubricated-to-frictional rheology transition, but the key results here are for stresses above the levels that cause extreme shear-thickening. At large solid fraction, φ, but below the stress-dependent jamming fraction, we find a critical φc(σ,μ) where σ is a dimensionless shear stress and μ is the interparticle friction coefficient. For φ>φc, the proportion of particles in rigid clusters grows sharply, as f rig |φ-φc|β with β=1/8. The fluctuations in the fraction of particles in rigid clusters yield a susceptibility measure rig |φ-φc|-γ with γ = 7/4. The system is thus found to exhibit criticality. The results are shown to depend on an effective field h(μ), which provides data collapse near φc for both f rig and rig. This behavior occurs over a range of stresses, with φc(σ,μ) increasing as the stress decreases.