Weak error estimates of fully-discrete schemes for the stochastic Cahn-Hilliard equation
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We study a class of fully-discrete schemes for the numerical approximation of solutions of stochastic Cahn–Hilliard equations with cubic nonlinearity and driven by additive noise. The spatial (resp. temporal) discretization is performed with a spectral Galerkin method (resp. a tamed exponential Euler method). We consider two situations: space-time white noise in dimension d=1 and trace-class noise in dimensions d=1,2,3. In both situations, we prove weak error estimates, where the weak order of convergence is twice the strong order of convergence with respect to the spatial and temporal discretization parameters. To prove these results, we show appropriate regularity estimates for solutions of the Kolmogorov equation associated with the stochastic Cahn–Hilliard equation, which have not been established previously and may be of interest in other contexts.
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