Spatially correlated rotational dynamics reveals strain dependence in amorphous particle packings

TL;DR

This study links microscopic particle rotations to the mechanical response of amorphous packings, showing that rotational dynamics are strain-sensitive and spatially correlated, providing new insights into the mechanics of disordered materials.

Contribution

It introduces the connection between particle rotational motion and the mechanics of athermal amorphous packings, highlighting the importance of rotations in understanding material behavior.

Findings

Rotational dynamics are highly strain sensitive.

Spatial correlations in rotation depend on friction and density.

Particle rotations are crucial for understanding amorphous material mechanics.

Abstract

Microstructural dynamics in amorphous particle packings is commonly probed by quantifying particle displacements. While rigidity in particle packings emerges when displacement of particles are hindered, it is not obvious how the typically disordered displacement metrics connect to mechanical response. Particle rotations, in contrast, are much less sensitive to confinement effects, while still sensitive to the mechanics of the packing. So far, little attention has been paid to connect microscopic rotational motion to mechanics of athermal amorphous packings. We demonstrate through experimental measurements that particle packing mechanics can be directly linked to the rotational motion of even round particles in a sheared packing. Our results show that the diffusive nature of rotational dynamics is highly strain sensitive. Additionally, there is substantial spatial correlation in rotation dynamics that is a function of the particle friction and packing density. Analysis of our measurements reveals that particle rotation dynamics plays an essential role in amorphous material mechanics.