# Asymptotics of work distributions in a stochastically driven system

**Authors:** Sreekanth K Manikandan, Supriya Krishnamurthy

arXiv: 1706.06489 · 2017-12-21

## TL;DR

This paper extends the EN theory to stochastically driven overdamped Langevin systems, providing exact asymptotic work distribution forms at arbitrary times and validating results with numerical simulations.

## Contribution

The paper develops an extension of EN theory to stochastic driving systems, deriving new analytic solutions for work distributions in such models.

## Key findings

- Derived asymptotic forms of work distributions at arbitrary times.
- Validated analytic solutions with numerical simulations.
- Compared steady-state dissipated work behavior with previous results.

## Abstract

We determine the asymptotic forms of work distributions at arbitrary times $T$, in a class of driven stochastic systems using a theory developed by Engel and Nickelsen (EN theory) (arXiv:1102.4505v1 [cond-mat.stat-mech]), which is based on the contraction principle of large deviation theory. In this paper, we extend the theory, previously applied in the context of deterministically driven systems, to a model in which the driving is stochastic. The models we study are described by overdamped Langevin equations and the work distributions in the path integral form, are characterised by having quadratic actions. We first illustrate EN theory, for a deterministically driven system - the breathing parabola model, and show that within its framework, the Crooks flucutation theorem manifests itself as a reflection symmetry property of a certain characteristic polynomial function. We then extend our analysis to a stochastically driven system, studied in ( arXiv:1212.0704v2 [cond-mat.stat-mech], arXiv:1402.5777v1 [cond-mat.stat-mech]) using a moment-generating-function method, for both equilibrium and non - equilibrium steady state initial distributions. In both cases we obtain new analytic solutions for the asymptotic forms of (dissipated) work distributions at arbitrary $T$. For dissipated work in the steady state, we compare the large $T$ asymptotic behaviour of our solution to that already obtained in ( arXiv:1402.5777v1 [cond-mat.stat-mech]). In all cases, special emphasis is placed on the computation of the pre-exponential factor and the results show excellent agreement with the numerical simulations. Our solutions are exact in the low noise limit.

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## Figures

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## References

42 references — full list in the complete paper: https://tomesphere.com/paper/1706.06489/full.md

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