Navier-Stokes equations on Riemannian manifolds
For mathematicians and physicists studying fluid dynamics on curved surfaces, this work provides theoretical insights but is incremental as it extends known formulations.
This paper studies Navier-Stokes equations on compact Riemannian manifolds, motivated by atmospheric models and thin film flows, and shows that Killing vector fields are essential for analyzing flow properties. Results include analysis of the linearized system and treatment of the 2D case with Coriolis effect.
We study properties of the solutions to Navier-Stokes system on compact Riemannian manifolds. The motivation for such a formulation comes from atmospheric models as well as some thin film flows on curved surfaces. There are different choices of the diffusion operator which have been used in previous studies, and we make a few comments why the choice adopted below seems to us the correct one. This choice leads to the conclusion that Killing vector fields are essential in analyzing the qualitative properties of the flow. We give several results illustrating this and analyze also the linearized version of Navier-Stokes system which is interesting in numerical applications. Finally we consider the 2 dimensional case which has specific characteristics, and treat also the Coriolis effect which is essential in atmospheric flows.