Journey of an intruder through the fluidisation and jamming transitions of a dense granular media

TL;DR

This study investigates how an intruder moves through dense granular media under vibration, revealing two key transitions: fluidisation and jamming, characterized by changes in motion, rheology, and structural reorganization.

Contribution

It provides experimental evidence of two distinct transitions in granular media, linking intruder dynamics to structural and rheological changes near jamming.

Findings

Identification of a fluidisation transition marked by a change from linear to stiff rheology.

Observation of a jamming transition characterized by bursty motion and critical scaling.

Detection of structural reorganization patterns evolving from compact to branched shapes.

Abstract

We study experimentally the motion of an intruder dragged into an amorphous monolayer of horizontally vibrated grains at high packing fractions. This motion exhibits two transitions. The first transition separates a continuous motion regime at comparatively low packing fractions and large dragging force from an intermittent motion one at high packing fraction and low dragging force. Associated to these different motions, we observe a transition from a linear rheology to a stiffer response. We thereby call "fluidisation" this first transition. A second transition is observed within the intermittent regime, when the intruder's motion is made of intermittent bursts separated by long waiting times. We observe a peak in the relative fluctuations of the intruder's displacements and a critical scaling of the burst amplitudes distributions. This transition occurs at the jamming point characterized in a previous study and defined as the point where the static pressure (i.e. the pressure measured in the absence of vibration) vanishes. Investigating the motion of the surrounding grains, we show that below the fluidisation transition, there is a permanent wake of free volume behind the intruder. This transition is marked by the evolution of the reorganization patterns around the intruder, which evolve from compact aggregates in the flowing regime to long-range branched shapes in the intermittent regime, suggesting an increasing role of the stress fluctuations. Remarkably, the distributions of the kinetic energy of these reorganization patterns also exhibits a critical scaling at the jamming transition.