Kolmogorov equations for stochastic convective Brinkman-Forchheimer equations forced by Lévy Noise and its application to infinite horizon problems

Abstract

This article examines the Kolmogorov equation corresponding to the following stochastic two- and three-dimensional incompressible (∇·u=0) convective Brinkman-Forchheimer equations, also known as the damped Navier-Stokes equations, driven by Lévy noise on the torus: align* du+[-μΔu+(u·∇)u+αu+β|u|r-1u+∇ p]d t =QdW+∫Zσ(t,z)π(d t,d z), align* where μ,α,β>0 are physical constants; Q is a non-negative, trace-class operator; W is a cylindrical Wiener process on a Hilbert space; σ represents the jump-noise coefficient; (Z,B(Z)) is a measurable space; π is a time-homogeneous Poisson random measure; and π denotes its compensator. The main contribution of this work is the establishment of the essential m-dissipativity of the corresponding Kolmogorov operator, a property that has received limited attention in the existing literature for systems driven by jump-type noise. Our main innovation is that, in contrast to traditional techniques which crucially depend on exponential moment estimates, we utilize the intrinsic structure of the absorption term αu+β|u|r-1u to dispense with these requirements. This allows us to establish the essential m-dissipativity of the Kolmogorov operator without the need for exponential moments. We apply the developed framework to an infinite-horizon stochastic optimal control problem, demonstrating the solvability of the associated infinite-dimensional Hamilton-Jacobi-Bellman (integro-differential) equation.