Cycle completion times probe interactions with environment

TL;DR

This paper introduces a basic model for cycle processes interacting with an environment, revealing complex behaviors like asymmetric cycle times, interaction-driven speeding, and dynamical phase transitions, aiding experimental interpretation.

Contribution

It develops a theoretical model for interacting cycle processes in non-equilibrium environments, highlighting rich behaviors not seen in single-particle systems.

Findings

Cycle times vary significantly with environmental conditions.

Asymmetries in forward and backward cycle times are observed.

Interactions can accelerate backward cycles and induce dynamical phase transitions.

Abstract

Recent measurements of durations of non-equilibrium processes provide valuable information on microscopic mechanisms and energetics. Comprehensive theory for corresponding experiments so far is well developed for single-particle systems only. Little is known for interacting systems in non-equilibrium environments. Here, we introduce and study a basic model for cycle processes interacting with an environment that can exhibit a net particle flow. We find a surprising richness of cycle time variations with environmental conditions. This manifests itself in unequal cycle times $\tau^+$ and $\tau^-$ in forward and backward cycle direction with both asymmetries $\tau^-<\tau^+$ and $\tau^->\tau^+$, speeding up of backward cycles by interactions, and dynamical phase transitions, where cycle times become multimodal functions of the bias. The model allows us to relate these effects to specific microscopic mechanisms, which can be helpful for interpreting experiments.