Inferring dissipation from current fluctuations
Abstract
Complex physical dynamics can often be modeled as a Markov jump process between mesoscopic configurations. When jumps between mesoscopic states are mediated by thermodynamic reservoirs, the time-irreversibility of the jump process is a measure of the physical dissipation. We rederive a recently introduced inequality relating the dissipation rate to current fluctuations in jump processes. We then adapt these results to diffusion processes via a limiting procedure, reaffirming that diffusions saturate the inequality. Finally, we study the impact of spatial coarse-graining in a two-dimensional model with driven diffusion. By observing fluctuations in coarse-grained currents, it is possible to infer a lower bound on the total dissipation rate, including the dissipation associated with hidden dynamics. The tightness of this bound depends on how well the spatial coarse-graining detects dynamical events that are driven by large thermodynamic forces.
Cite
@article{arxiv.1609.07131,
title = {Inferring dissipation from current fluctuations},
author = {Todd R. Gingrich and Grant M. Rotskoff and Jordan M. Horowitz},
journal= {arXiv preprint arXiv:1609.07131},
year = {2017}
}
Comments
14 pages, 10 figures