Numerical Analysis of 2D Stochastic Navier--Stokes Equations with Transport Noise: Regularity and Spatial Semidiscretization
Abstract
This paper establishes strong convergence rates for the spatial finite element discretization of a two-dimensional stochastic Navier--Stokes system with transport noise and no-slip boundary conditions on a convex polygonal domain. The main challenge arises from the lack of spatial \(D(A)\)-regularity of the solution (where \(A\) is the Stokes operator), which prevents the application of standard error analysis techniques. Under a small-noise assumption, we prove that the weak solution satisfies \[ u ∈ L2(; C([0,T]; Hσ) L2(0,T; Hσ1+)) \] for some \( ∈ (0,12)\). To address the low regularity in the numerical analysis, we introduce a novel smoothing operator \(Jh,α = AhαPh A-α\) with \(α ∈ (0,1)\), where \(Ah\) is the discrete Stokes operator and \(Ph\) the discrete Helmholtz projection. This tool enables a complete error analysis for a MINI-element spatial semidiscretization, yielding the mean-square convergence estimate \[ \|u - uh\|L2(; C([0,T]; L2( O;R2))) + \|∇(u - uh)\|L2( × (0,T); L2(O;R2×2)) ≤slant c\, h (1 + 1h). \] The framework can be extended to broader stochastic fluid models with rough noise and Dirichlet boundary conditions.
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