# Stochastic dynamics and thermodynamics around a metastable state based   on the linear Dean-Kawasaki equation

**Authors:** Hiroshi Frusawa

arXiv: 1812.02951 · 2018-12-10

## TL;DR

This paper linearizes the Dean-Kawasaki equation around a metastable state to analyze stochastic thermodynamics and compare dynamics with equilibrium, revealing differences in density and diffusion in hard sphere fluids.

## Contribution

It introduces a linearized form of the Dean-Kawasaki equation around metastable states and develops a field theoretic approach linking stochastic dynamics with equilibrium DFT.

## Key findings

- Heat dissipation into the reservoir is negligible on average.
- Metastable density is larger than equilibrium density.
- Effective diffusion constant is smaller in metastable states.

## Abstract

The Dean-Kawasaki equation forms the basis of the stochastic density functional theory (DFT). Here it is demonstrated that the Dean-Kawasaki equation can be directly linearized in the first approximation of the driving force due to the free energy functional $F[\rho] $ of an instantaneous density distribution $\rho$, when we consider small density fluctuations around a metastable state whose density distribution $\rho^*$ is determined by the stationary equation $\delta F[\rho]/\delta \rho|_{\rho=\rho^*}=\mu$ with $\mu$ denoting the chemical potential. Our main results regarding the linear Dean-Kawasaki equation are threefold. First, (i) the corresponding stochastic thermodynamics has been formulated, showing that the heat dissipated into the reservoir is negligible on average. Next, (ii) we have developed a field theoretic treatment combined with the equilibrium DFT, giving an approximate form of $F[\rho]$ that is related to the equilibrium free energy functional. Accordingly, (iii) the linear Dean-Kawasaki equation, which has been reduced to a tractable form expressed by the direct correlation function, allows us to compare the stochastic dynamics around metastable and equilibrium states, particularly in the Percus-Yevick hard sphere fluids; we have found that the metastable density is larger and the effective diffusion constant in the metastable state is smaller than the equilibrium ones in repulsive fluids.

## Full text

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## References

48 references — full list in the complete paper: https://tomesphere.com/paper/1812.02951/full.md

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Source: https://tomesphere.com/paper/1812.02951