Resonance-based integrators for stochastic Schr\"odinger equations. Convergence and long-time error bounds

Abstract

We develop resonance-based low-regularity numerical integrators for stochastic Schr"odinger equations with additive Q-Wiener noise, covering both the linear equation with rough potential and the cubic nonlinear case. For the linear problem, we prove strong and almost sure convergence, achieving first-order accuracy in Hσ for solutions in Hσ+1, improving the classical Hσ+2 requirement. In a regime of O(2) potentials and O() noise, we establish uniform moment bounds up to times O(-2) and construct a non-resonant scheme with long-time error O(2τ). For the cubic case, we derive analogous pathwise convergence results at low regularity. In the weakly nonlinear stochastic regime, we obtain long-time pathwise errors of size O(2τδ), for any δ<1, up to times O(-2). The analysis relies on a novel extension of the regularity-compensation oscillation (RCO) technique to the stochastic setting, overcoming the loss of temporal regularity induced by stochastic convolutions and yielding an O(2) improvement in long-time error bounds. To the best of our knowledge, this is the first work establishing long-time error bounds for low-regularity integrators for stochastic dispersive equations. Numerical experiments support the theory.

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