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Hauptverfasser: Glatt-Holtz, Nathan E., Martinez, Vincent R., Nguyen, Hung D.
Format: Preprint
Veröffentlicht: 2022
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Online-Zugang:https://arxiv.org/abs/2212.05646
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author Glatt-Holtz, Nathan E.
Martinez, Vincent R.
Nguyen, Hung D.
author_facet Glatt-Holtz, Nathan E.
Martinez, Vincent R.
Nguyen, Hung D.
contents We consider a class of semi-linear differential Volterra equations with polynomial-type potentials that incorporates the effects of memory while being subjected to random perturbations via an additive Gaussian noise. Our main study is the long time statistics of the system in the singular regime as the memory kernel collapses to a Dirac function. Specifically, we show that provided that sufficiently many directions in the phase space are stochastically forced, there is a unique invariant probability measure to which the system converges, with respect to a suitable Wasserstein-type topology, and at an exponential rate which is independent of the decay rate of the memory kernel. We then prove the convergence of this unique statistically steady state to the unique invariant probability measure of the classical stochastic reaction-diffusion equation in the zero-memory limit. Consequently, we establish the global-in-time validity of the short memory approximation.
format Preprint
id arxiv_https___arxiv_org_abs_2212_05646
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle The short memory limit for long time statistics in a stochastic Coleman-Gurtin model of heat conduction
Glatt-Holtz, Nathan E.
Martinez, Vincent R.
Nguyen, Hung D.
Probability
Analysis of PDEs
We consider a class of semi-linear differential Volterra equations with polynomial-type potentials that incorporates the effects of memory while being subjected to random perturbations via an additive Gaussian noise. Our main study is the long time statistics of the system in the singular regime as the memory kernel collapses to a Dirac function. Specifically, we show that provided that sufficiently many directions in the phase space are stochastically forced, there is a unique invariant probability measure to which the system converges, with respect to a suitable Wasserstein-type topology, and at an exponential rate which is independent of the decay rate of the memory kernel. We then prove the convergence of this unique statistically steady state to the unique invariant probability measure of the classical stochastic reaction-diffusion equation in the zero-memory limit. Consequently, we establish the global-in-time validity of the short memory approximation.
title The short memory limit for long time statistics in a stochastic Coleman-Gurtin model of heat conduction
topic Probability
Analysis of PDEs
url https://arxiv.org/abs/2212.05646