2014
DOI: 10.1007/s00220-014-2233-4
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The Smoluchowski-Kramers Limit of Stochastic Differential Equations with Arbitrary State-Dependent Friction

Abstract: We study a class of systems of stochastic differential equations describing diffusive phenomena. The Smoluchowski-Kramers approximation is used to describe their dynamics in the small mass limit. Our systems have arbitrary state-dependent friction and noise coefficients. We identify the limiting equation and, in particular, the additional drift term that appears in the limit is expressed in terms of the solution to a Lyapunov matrix equation. The proof uses a theory of convergence of stochastic integrals devel… Show more

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Cited by 84 publications
(146 citation statements)
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References 35 publications
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“…Nevertheless this heuristic, first employed by Smoluchowski in [17] and later by Kramers in [10], serves as a good first step in understanding how some parts of (2.1) arise. See [7] for further, more specific details in how the noise-induced drift term, i.e. S(x(t)), in equation (2.1) is produced.…”
Section: Resultsmentioning
confidence: 99%
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“…Nevertheless this heuristic, first employed by Smoluchowski in [17] and later by Kramers in [10], serves as a good first step in understanding how some parts of (2.1) arise. See [7] for further, more specific details in how the noise-induced drift term, i.e. S(x(t)), in equation (2.1) is produced.…”
Section: Resultsmentioning
confidence: 99%
“…In essence, provided the friction matrix γ(x) is positive-definite for each x ∈ X , our main result shows that we can still extract convergence of x m (t) as m → 0 pathwise on bounded time intervals in probability, without making strong boundedness assumptions on the coefficients F, γ, σ and their derivatives. These boundedness assumptions were made in the earlier work [7] and have also been made previously in other, related works [2,3,16]. From a physical standpoint, however, there are many natural model equations that do not satisfy these strong boundedness requirements, and therefore the use of the small-mass approximation of the dynamics above is in question.…”
Section: −γ(X M (T))v M (T) Dt) and A Force (F(x M (T)) Dt)mentioning
confidence: 89%
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“…Whereas the Langevin equations are convenient for simulations, a statistical description is often preferred for theoretical analysis. To this end one derives the Fokker-Planck equation for the position degrees of freedom, which for a Brownian particle subject to inhomogeneous Lorentz force, is given as [2,5] ∂P (r, t) ∂t = ∇ · D(r)∇P (r, t) ,…”
Section: Introductionmentioning
confidence: 99%
“…Due to the nonconservative nature of the Lorentz force, the overdamped equation of motion cannot be obtained by simply setting the mass of the particles to zero [4,42]. Though there exists a nontrivial limiting procedure [43][44][45] that yields the small-mass limit of the (velocity) Langevin equation, the resulting overdamped equation is not suitable for determining velocity dependent variables such as flux and entropy [4,5,[46][47][48] despite the fact that it captures the position statistics accurately. In this work, we have avoided these problems by performing simulations using the (velocity) Langevin equation with a finite but small mass.…”
Section: Introductionmentioning
confidence: 99%