Christian Hamster scite author profile

We consider reaction-diffusion equations that are stochastically forced by a small multiplicative noise term. We show that spectrally stable traveling wave solutions to the deterministic system retain their orbital stability if the amplitude of the noise is sufficiently small.By applying a stochastic phase-shift together with a time-transform, we obtain a semilinear SPDE that describes the fluctuations from the primary wave. We subsequently develop a semigroup approach to handle the nonlinear stability question in a fashion that is closely related to modern deterministic methods.

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Stability of Traveling Waves for Systems of Reaction-Diffusion Equations with Multiplicative Noise

Hamster¹,

Hupkes²

2020

SIAM J. Math. Anal.

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We consider reaction-diffusion equations that are stochastically forced by a small multiplicative noise term. We show that spectrally stable traveling wave solutions to the deterministic system retain their orbital stability if the amplitude of the noise is sufficiently small.By applying a stochastic phase-shift together with a time-transform, we obtain a quasi-linear SPDE that describes the fluctuations from the primary wave. We subsequently follow the semigroup approach developed in [17] to handle the nonlinear stability question. The main novel feature is that we no longer require the diffusion coefficients to be equal.

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Travelling waves for reaction–diffusion equations forced by translation invariant noise

Hamster

Hupkes

2020

Physica D: Nonlinear Phenomena

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Inspired by applications, we consider reaction-diffusion equations on R that are stochastically forced by a small multiplicative noise term that is white in time, coloured in space and invariant under translations. We show how these equations can be understood as a stochastic partial differential equation (SPDE) forced by a cylindrical Q-Wiener process and subsequently explain how to study stochastic travelling waves in this setting. In particular, we generalize the phase tracking framework that was developed in [16,17] for noise processes driven by a single Brownian motion. The main focus lies on explaining how this framework naturally leads to long term approximations for the stochastic wave profile and speed. We illustrate our approach by two fully worked-out examples, which highlight the predictive power of our expansions.

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Stability of Traveling Waves for Systems of Reaction-Diffusion Equations with Multiplicative Noise

Hamster¹,

Hupkes²

2018

Preprint

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Stability of Traveling Waves on Exponentially Long Timescales in Stochastic Reaction-Diffusion Equations

Hamster¹,

Hupkes²

2020

SIAM J. Appl. Dyn. Syst.

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