Quaking in Soft Granular Particles with Speed-dependent Friction: Role of Critical Volume Fraction and Inertia

Abstract

Our previous numerical simulation [C.-E. Tsai et al., Physical Review Research 6, 023065 (2024)] has shown that, for soft granular particles under quasistatic shearing, incorporating a speed-dependent friction is essential to reproduce the rate-dependent stick-slip fluctuations that have been found in the laboratory experiment [J.-C. Tsai et al., Physical Review Letters 126, 128001 (2021)]. As a continuation, here we employ the simulation in a wide range of driving speeds to examine the role of grain inertia in the quaking dynamics. With our Stribeck-Hertz model, we find that having the volume fraction exceeding a critical value φc is a necessary condition for the quaking to occur, and that the value of φc is determined by material parameters only, independent of the driving rate. The effect of grain inertia generally suppresses the occurrence of quaking, and we conclude by presenting the state diagrams which exhibit a progressive narrowing of the quaking regime as the driving speed increases and the disappearance of quaking at an extremely high shear rate.