Numerical simulation of two-dimensional incompressible Navier-Stokes turbulence by Clebsch potentials (2305.16673v1)

Abstract: The Clebsch representation of a velocity field represents an effective tool for the analysis of physical properties of fluid flows. Indeed, a suitable choice of Clebsch potentials can be used to extract structural features that would otherwise be hidden within the complexity of fluid patterns and their evolution. In this work, we report the solution of the two-dimensional incompressible Navier-Stokes equations via Clebsch potentials. The results are in agreement with the solution of the vorticity equation for the stream function. Furthermore, we numerically demonstrate that the Shannon information entropy associated with each Clebsch potential is a growing function of time, and that it evolves at a slower rate than the rate of change in energy and enstrophy, as predicted by theory. These results pave the way for an alternative approach in the numerical study of fluid flows.