The invariance principle for nonlinear Fokker--Planck equations

Abstract

One studies here, via the La Salle invariance principle for nonlinear semigroups in Banach spaces, the properties of the ω-limit set ω(u0) corresponding to the orbit γ(u0)=\u(t,u0);\ t0\, where u=u(t,u0) is the solution to the nonlinear Fokker-Planck equation arrayl ut-β(u)+ div(Db(u)u)=0\ in (0,∞)×Rd,\\ u(0,x)=u0(x),\ \ x∈Rd, u0∈ L1(Rd),\ d3.array Here, β∈ C1(R) and β'(r)>0, ∀ r0. Moreover, β is a sublinear function, possibly degenerate in the origin, b∈ C1(R), b bounded, b b0∈(0,∞), D is bounded such that D=-∇, where ∈ C(Rd) is such that 1, (x)∞ as |x|∞ and satisfies a condition of the form -α|∇|20, a.e. on Rd. The main conclusion is that the equation has an equilibrium state and the set ω(u0) is a non-empty, compact subset of L1(Rd) while, for each t0, the operator u0 u(t,u0) is an isometry on ω(u0). In the nondegenerate case 0<γ0β'γ1 studied in [Barbu, R\"ockner: arXiv:1808.10706], it follows that t∞S(t)u0=u∞ in L1(Rd), where u∞ is the unique bounded stationary solution to the equation.