Protocol-Dependence and State Variables in the Force-Moment Ensemble
Abstract
Stress-based ensembles incorporating temperature-like variables have been proposed as a route to an equation of state for granular materials. To test the efficacy of this approach, we perform experiments on a two-dimensional photoelastic granular system under three loading conditions: uniaxial compression, biaxial compression, and simple shear. From the interparticle forces, we find that the distributions of the normal component of the coarse-grained force-moment tensor are exponential-tailed, while the deviatoric component is Gaussian-distributed. This implies that the correct stress-based statistical mechanics conserves both the force-moment tensor and the Maxwell-Cremona force-tiling area. As such, two variables of state arise: the tensorial angoricity () and a new temperature-like quantity associated with the force-tile area which we name {\it keramicity} (). Each quantity is observed to be inversely proportional to the global confining pressure; however only exhibits the protocol-independence expected of a state variable, while behaves as a variable of process.
Cite
@article{arxiv.1802.09641,
title = {Protocol-Dependence and State Variables in the Force-Moment Ensemble},
author = {Ephraim S. Bililign and Jonathan E. Kollmer and Karen E. Daniels},
journal= {arXiv preprint arXiv:1802.09641},
year = {2019}
}