On the uniqueness of continuous inverse kinetic theory for incompressible fluids

TL;DR

This paper investigates the uniqueness of inverse kinetic theories for incompressible fluids, demonstrating that under certain assumptions, the kinetic equation is uniquely determined and consistent with energy and entropy principles.

Contribution

It proves that the inverse kinetic equation can be uniquely defined as a Fokker-Planck type under specific assumptions, ensuring consistency with fluid energy and entropy.

Findings

Kinetic equation uniqueness is established under Fokker-Planck assumptions.

The Fokker-Planck coefficients are uniquely determined by prescribed conditions.

The inverse kinetic equation satisfies both an entropy principle and the fluid energy equation.

Abstract

Fundamental aspects of inverse kinetic theories for incompressible Navier-Stokes equations concern the possibility of defining uniquely the kinetic equation underlying such models and furthermore, the construction of a kinetic theory implying also the energy equation. The latter condition is consistent with the requirement that fluid fields result classical solutions of the fluid equations. These issues appear of potential relevance both from the mathematical viewpoint and for the physical interpretation of the theory. In this paper we intend to prove that the non-uniqueness feature can be resolved by imposing suitable assumptions. These include, in particular, the requirement that the kinetic equation be equivalent, in a suitable sense, to a Fokker-Planck kinetic equation. Its Fokker-Planck coefficients are proven to be uniquely determined by means of appropriate prescriptions. In addition, as a further result, it is proven that the inverse kinetic equation satisfies both an entropy principle and the energy equation for the fluid fields.