Litcius/Paper detail

Stress-activated constraints in dense suspension rheology

Abhinendra Singh, Grayson L. Jackson, Michael van der Naald, Juan Pablo, Heinrich M. Jaeger

2022Physical Review Fluids31 citationsDOIOpen Access PDF

Abstract

Dispersing small particles in a liquid can produce surprising behaviors when the solids fraction becomes large: rapid shearing drives these systems out of equilibrium and can lead to dramatic increases in viscosity (shear-thickening) or even solidification (shear jamming). These phenomena occur above a characteristic onset stress when particles are forced into frictional contact. Here we show via simulations how this can be understood within a framework that abstracts details of the forces acting at particle-particle contacts into general stress-activated constraints on relative particle movement. We find that focusing on just two constraints, affecting sliding and rolling at contact, can reproduce the experimentally observed shear thickening behavior quantitatively, despite widely different particle properties, surface chemistries, and suspending fluids. Within this framework parameters such as coefficients of sliding and rolling friction can each be viewed as a proxy for one or more forces of different physical or chemical origin, while the parameter magnitudes indicate the relative importance of the associated constraint. In this way, a new link is established that connects features observable in macroscale rheological measurements to classes of constraints arising from micro- or nano-scale properties.

Topics & Concepts

RheologyDilatantMechanicsShearing (physics)Particle (ecology)Materials scienceShear (geology)Statistical physicsViscosityClassical mechanicsPhysicsComposite materialGeologyOceanographyGranular flow and fluidized bedsMaterial Dynamics and PropertiesRheology and Fluid Dynamics Studies