On the equilibrium solutions in a model for electro-energy-reaction-diffusion systems

Electro-energy-reaction-diffusion systems are thermodynamically consistent continuum models for reaction-diffusion processes that account for temperature and electrostatic effects in a way that total charge and energy are conserved. The question of the long-time asymptotic behavior in electro-energy-reaction-diffusion systems and the characterization of their equilibrium solutions leads to a maximization problem of the entropy on the manifold of states with fixed values for the linear charge and the nonlinear energy functional. As the main result, we establish the existence, uniqueness, and regularity of solutions to this constrained optimization problem. Important ingredients in the proof are tools from convex analysis and a reduced version of the Lagrange functional. We also derive the time-dependent PDE system in the framework of gradient systems, and we discuss the relations between stationary states, critical points, and local equilibria.