A Finite Element Method for Fluctuating Navier--Stokes Equations

We introduce a finite-element framework for simulating thermal fluctuations in compressible fluids governed by the fluctuating Navier-Stokes equations.

The method is designed to preserve the fundamental fluctuation-dissipation balance at the discrete level.

This is achieved by defining the stochastic forcing term in the weak formulation, ensuring its covariance is proportional to the discrete viscous dissipation operator.

A nodal quadrature rule is employed to eliminate unphysical mesh-scale correlations.

The time integration is performed using the Crank-Nicolson scheme to maintain numerical stability and accuracy.

The proposed approach is numerically validated in one, two, and three spatial dimensions, demonstrating its capability to correctly capture equilibrium fluctuation statistics across various discretisation parameters.