Langevin dynamics with variable coefficients and nonconservative forces: From stationary states to numerical methods

Matthias Sachs; Benedict Leimkuhler; Vincent Danos

doi:10.3390/e19120647

Langevin dynamics with variable coefficients and nonconservative forces: From stationary states to numerical methods

Matthias Sachs, Benedict Leimkuhler^*, Vincent Danos

^*Corresponding author for this work

Mathematics

Research output: Contribution to journal › Article › peer-review

19 Citations (Scopus)

Abstract

Langevin dynamics is a versatile stochastic model used in biology, chemistry, engineering, physics and computer science. Traditionally, in thermal equilibrium, one assumes (i) the forces are given as the gradient of a potential and (ii) a fluctuation-dissipation relation holds between stochastic and dissipative forces; these assumptions ensure that the system samples a prescribed invariant Gibbs-Boltzmann distribution for a specified target temperature. In this article, we relax these assumptions, incorporating variable friction and temperature parameters and allowing nonconservative force fields, for which the form of the stationary state is typically not known a priori. We examine theoretical issues such as stability of the steady state and ergodic properties, as well as practical aspects such as the design of numerical methods for stochastic particle models. Applications to nonequilibrium systems with thermal gradients and active particles are discussed.

Original language	English
Article number	647
Journal	Entropy
Volume	19
Issue number	12
DOIs	https://doi.org/10.3390/e19120647
Publication status	Published - 1 Dec 2017

Bibliographical note

Funding Information:
Acknowledgments: The research of all three authors was supported by the ERC project RULE (grant number 320823). The collaboration was initiated during a residency of the first two authors at the Institut Henri Poincaré and its program on “Stochastic dynamics out of equilibrium.” The work of M. Sachs was further supported by the Statistical and Applied Mathematical Sciences Institute (North Carolina).

Publisher Copyright:
© 2017 by the authors.

Keywords

Fluctuation-dissipation theorems
Langevin dynamics
Local thermal equilibrium
Molecular dynamics
Nonequilibrium simulation
Sampling
Temperature gradients

ASJC Scopus subject areas

Information Systems
Mathematical Physics
Physics and Astronomy (miscellaneous)
Electrical and Electronic Engineering

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10.3390/e19120647

Cite this

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title = "Langevin dynamics with variable coefficients and nonconservative forces: From stationary states to numerical methods",

abstract = "Langevin dynamics is a versatile stochastic model used in biology, chemistry, engineering, physics and computer science. Traditionally, in thermal equilibrium, one assumes (i) the forces are given as the gradient of a potential and (ii) a fluctuation-dissipation relation holds between stochastic and dissipative forces; these assumptions ensure that the system samples a prescribed invariant Gibbs-Boltzmann distribution for a specified target temperature. In this article, we relax these assumptions, incorporating variable friction and temperature parameters and allowing nonconservative force fields, for which the form of the stationary state is typically not known a priori. We examine theoretical issues such as stability of the steady state and ergodic properties, as well as practical aspects such as the design of numerical methods for stochastic particle models. Applications to nonequilibrium systems with thermal gradients and active particles are discussed.",

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author = "Matthias Sachs and Benedict Leimkuhler and Vincent Danos",

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AU - Danos, Vincent

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N2 - Langevin dynamics is a versatile stochastic model used in biology, chemistry, engineering, physics and computer science. Traditionally, in thermal equilibrium, one assumes (i) the forces are given as the gradient of a potential and (ii) a fluctuation-dissipation relation holds between stochastic and dissipative forces; these assumptions ensure that the system samples a prescribed invariant Gibbs-Boltzmann distribution for a specified target temperature. In this article, we relax these assumptions, incorporating variable friction and temperature parameters and allowing nonconservative force fields, for which the form of the stationary state is typically not known a priori. We examine theoretical issues such as stability of the steady state and ergodic properties, as well as practical aspects such as the design of numerical methods for stochastic particle models. Applications to nonequilibrium systems with thermal gradients and active particles are discussed.

AB - Langevin dynamics is a versatile stochastic model used in biology, chemistry, engineering, physics and computer science. Traditionally, in thermal equilibrium, one assumes (i) the forces are given as the gradient of a potential and (ii) a fluctuation-dissipation relation holds between stochastic and dissipative forces; these assumptions ensure that the system samples a prescribed invariant Gibbs-Boltzmann distribution for a specified target temperature. In this article, we relax these assumptions, incorporating variable friction and temperature parameters and allowing nonconservative force fields, for which the form of the stationary state is typically not known a priori. We examine theoretical issues such as stability of the steady state and ergodic properties, as well as practical aspects such as the design of numerical methods for stochastic particle models. Applications to nonequilibrium systems with thermal gradients and active particles are discussed.

KW - Fluctuation-dissipation theorems

KW - Langevin dynamics

KW - Local thermal equilibrium

KW - Molecular dynamics

KW - Nonequilibrium simulation

KW - Sampling

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Langevin dynamics with variable coefficients and nonconservative forces: From stationary states to numerical methods

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

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