Avalanche-like fluidization of a non-Brownian particle gel

TL;DR

This study investigates the fluidization process of a non-Brownian particle gel under shear, revealing avalanche-like events and shear banding behaviors influenced by aging and shear rate, with implications for understanding complex flow dynamics.

Contribution

It provides detailed experimental insights into the transient fluidization mechanisms of attractive particle gels, highlighting avalanche-like events and the effects of aging and shear rate.

Findings

Fluidization occurs via successive steps with peaks in stress relaxation.

Shear banding can be transient or steady-state, depending on conditions.

Critical shear rate depends on shear cell width and aging time.

Abstract

We report on the fluidization dynamics of an attractive gel composed of non-Brownian particles made of fused silica colloids. Extensive rheology coupled to ultrasonic velocimetry allows us to characterize the global stress response together with the local dynamics of the gel during shear startup experiments. In practice, after being rejuvenated by a preshear, the gel is left to age during a time $t_w$ before being submitted to a constant shear rate $\dot \gamma$. We investigate in detail the effects of both $t_w$ and $\dot \gamma$ on the fluidization dynamics and build a detailed state diagram of the gel response to shear startup flows. The gel may either display transient shear banding towards complete fluidization, or steady-state shear banding. In the former case, we unravel that the progressive fluidization occurs by successive steps that appear as peaks on the global stress relaxation signal. Flow imaging reveals that the shear band grows up to complete fluidization of the material by sudden avalanche-like events which are distributed heterogeneously along the vorticity direction and correlated to large peaks in the slip velocity at the moving wall. These features are robust over a wide range of values of $t_w$ and $\dot \gamma$, although the very details of the fluidization scenario vary with $\dot \gamma$. Finally, the critical shear rate $\dot \gamma^*$ that separates steady-state shear-banding from steady-state homogeneous flow depends on the width on the shear cell and exhibits a nonlinear dependence with $t_w$. Our work brings about valuable experimental data on transient flows of attractive dispersions, highlighting the subtle interplay between shear, wall slip and aging which modeling constitutes a major challenge that has not been met yet.