A finite element approximation for the stochastic Landau-Lifshitz-Gilbert equation
Provides a numerical method for simulating magnetization dynamics under random fluctuations, relevant for researchers in micromagnetics and stochastic PDEs.
The authors reformulate the stochastic Landau-Lifshitz-Gilbert equation and propose a convergent θ-linear scheme that avoids nonlinear systems and step-size restrictions for θ in (1/2,1], proving existence of weak martingale solutions.
The stochastic Landau--Lifshitz--Gilbert (LLG) equation describes the behaviour of the magnetization under the influence of the effective field consisting of random fluctuations. We first reformulate the equation into an equation the unknown of which is differentiable with respect to the time variable. We then propose a convergent $θ$-linear scheme for the numerical solution of the reformulated equation. As a consequence, we show the existence of weak martingale solutions to the stochastic LLG equation. A salient feature of this scheme is that it does not involve a nonlinear system, and that no condition on time and space steps is required when $θ\in(\frac{1}{2},1]$. Numerical results are presented to show the applicability of the method.