Granular piston-probing in microgravity: powder compression, from densification to jamming

TL;DR

This study investigates how microgravity affects powder densification and jamming during piston compression, revealing that jamming occurs at lower densities in microgravity due to altered granular fabric and force interactions.

Contribution

It provides new insights into granular behavior in microgravity, showing that jamming occurs at lower packing fractions and highlighting the role of gravitational forces in particle reorganization.

Findings

Jamming occurs at lower packing fraction in microgravity ($oxed{0.567}$) than on ground ($oxed{0.579}$).

Microgravity alters the granular fabric, reducing the density at which particles become stable.

Cohesive interactions become more significant in low gravity, influencing force balance and packing stability.

Abstract

The macroscopic response of granular solids is determined by the microscopic fabric of force chains, which, in turn, is intimately linked to the history of the solid. To query the influence of gravity on powder flow-behavior, a granular material is subjected to compression by a piston in a closed container, on-ground and in microgravity. Results show that piston-probing densifies the packing, eventually leading to jamming of the material compressed by the piston, regardless of the gravitational environment. The onset of jamming is found to appear at lower packing fraction in microgravity ($\varphi^{\textrm{$\mu$-g}}_J = 0.567 \pm 0.014$) than on-ground ($\varphi^{\text{gnd}}_J = 0.579 \pm 0.014 $). We interpret these findings as the manifestation of a granular fabric altered by the gravitational force field: in absence of a secondary load (due to gravitational acceleration) to stimulate reorganization in a different direction to the major compression stress, the particles' configuration becomes stable at lower density, as the particles have no external drive to promote reorganization into a denser packing. This is coupled with a change in interparticular force balance which takes place under low gravity, as cohesive interactions become predominant. We propose a combination of microscopic and continuum arguments to rationalize our results.