Traction chain networks: Insights beyond force chain networks for non-spherical particle systems

TL;DR

This paper introduces traction chain networks as an extension to force chain networks to better characterize contact states in non-spherical granular materials, addressing limitations of force chains in such systems.

Contribution

The paper proposes traction chain networks to complement force chain networks, enabling more complete contact state characterization in non-spherical particle systems.

Findings

Force chain networks are sufficient for spherical particles but not for non-spherical particles.

Traction chain networks provide additional information to define contact states.

Enhanced quantification of granular contact states in non-spherical systems.

Abstract

Force chain networks are generally applied in granular materials to gain insight into inter-particle granular contact. For conservative spherical particle systems, i.e. frictionless and undamped, force chains are information complete due to symmetries resulting from isotropy and constant curvature of a sphere. In fact, for conservative spherical particle systems, given the geometry and material, the force chain network uniquely defines the contact state that includes elastic forces, penetration distance, overlap volume, contact areas and contact pressures in a particle system. This is, however, not the case for conservative non-spherical particle systems. The reason is that a force chain network is not sufficient to uniquely define the contact state in a conservative non-spherical particle system. Additional information is required to define the contact state of non-spherical granular systems. Traction chain networks are proposed to complement force chain networks for the improved quantification of the state of contact of a granular system.