Validity of the stochastic Ginzburg-Landau approximation in higher space dimensions -A Wiener algebra approach-

Abstract

We consider an anisotropic d-dimensional Swift-Hohenberg model O(2) -close to the first instability, where 0 < 1 is a small perturbation parameter. This model for pattern formation is perturbed with additive noise in time and space. By a multiple scaling ansatz we derive a stochastic d -dimensional Ginzburg-Landau equation for the approximate description of the bifurcating solutions. We prove the validity of the approximation by this amplitude equation on its natural time scale in case of d -dimensional periodic domains of length O(1/) for the Swift-Hohenberg model under suitable conditions on the additive noise. In detail, we prove the validity of this approximation for noise whose set of Fourier coefficients with respect to x is in 1 for fixed t ≥ 0 . Moreover, we improve existing approximation results in the sense that the stable part of the noise can be larger.