Learning a potential formulation for rate-and-state friction
Abstract
Empirical rate-and-state friction laws are widely used in geophysics and engineering to simulate interface slip. They postulate that the friction coefficient depends on the local slip rate and a state variable that reflects the history of slip. Depending on the parameters, rate-and-state friction can be either rate-strengthening, leading to steady slip, or rate-weakening, leading to unsteady stick-slip behavior modeling earthquakes. Rate-and-state friction does not have a potential or variational formulation, making implicit solution approaches difficult and implementation numerically expensive. In this work, we propose a potential formulation for the rate-and-state friction. We formulate the potentials as neural networks and train them so that the resulting behavior emulates the empirical rate-and-state friction. We show that this potential formulation enables implicit time discretization leading to efficient numerical implementation.
Keywords
Cite
@article{arxiv.2507.09796,
title = {Learning a potential formulation for rate-and-state friction},
author = {Shengduo Liu and Kaushik Bhattacharya and Nadia Lapusta},
journal= {arXiv preprint arXiv:2507.09796},
year = {2025}
}