English

Using tensor network states for multi-particle Brownian ratchets

Statistical Mechanics 2022-06-22 v2

Abstract

The study of Brownian ratchets has taught how time-periodic driving supports a time-periodic steady state that generates nonequilibrium transport. When a single particle is transported in one dimension, it is possible to rationalize the current in terms of the potential, but experimental efforts have ventured beyond that single-body case to systems with many interacting carriers. Working with a lattice model of volume-excluding particles in one dimension, we analyze the impact of interactions on a flashing ratchet's current. To surmount the many-body problem, we employ the time-dependent variational principle with a binary tree tensor network, methods discussed at length in a companion paper. Rather than propagating individual trajectories, the tensor network approach propagates a distribution over many-body configurations via a controllable variational approximation. The calculations, which reproduce Gillespie trajectory sampling, identify and explain a shift in the frequency of maximum current to higher driving frequency as the lattice occupancy increases.

Keywords

Cite

@article{arxiv.2201.03531,
  title  = {Using tensor network states for multi-particle Brownian ratchets},
  author = {Nils E. Strand and Hadrien Vroylandt and Todd R. Gingrich},
  journal= {arXiv preprint arXiv:2201.03531},
  year   = {2022}
}

Comments

6 pages, 3 figures

R2 v1 2026-06-24T08:45:23.277Z