Global wellposedness for a class of reaction-advection-anisotropic-diffusion systems

TL;DR

This paper establishes the global existence and uniqueness of solutions for reaction-advection-anisotropic-diffusion systems with time-space dependent coefficients, extending previous results and applying to models in porous media and chemical reactions.

Contribution

It extends prior work by proving well-posedness for systems with time-space dependent anisotropic diffusion and advection, using optimal $L^p$-maximal regularity techniques.

Findings

Proves global well-posedness for a broad class of reaction-advection-diffusion systems.

Extends $L^2$-estimates to anisotropic and advection-including frameworks.

Provides applications to chemically reacting systems with mass-action kinetics.

Abstract

We prove existence and uniqueness of global solutions for a class of reaction-advection-anisotropic-diffusion systems whose reaction terms have a "triangular structure". We thus extend previous results to the case of time-space dependent anisotropic diffusions and with time-space dependent advection terms. The corresponding models are in particular relevant for transport processes inside porous media and in situations in which additional migration occurs. The proofs are based on optimal $L^p$-maximal regularity results for the general time-dependent linear operator dual to the one involved in the considered systems. As an application, we prove global well-posedness for a prototypical class of chemically reacting systems with mass-action kinetics, involving networks of reactions of the type $C_1+\ldots+C_{P-1} \rightleftharpoons C_{P} $. Finally, we analyze how a classical a priori $L^2$-estimate of the solutions, which holds with this kind of nonlinear reactive terms, extends to our general anisotropic-advection framework. It does extend with the same assumptions for isotropic diffusions and is replaced by an $L^{(N+1)/N}$-estimate in the general situation.