Nonlocal nonlinear diffusion equations. Smoothing effects, Green functions, and functional inequalities

Abstract

We establish boundedness estimates for solutions of generalized porous medium equations of the form ∂t u+(-L)[um]=0 RN×(0,T), where m≥1 and -L is a linear, symmetric, and nonnegative operator. The wide class of operators we consider includes, but is not limited to, L\'evy operators. Our quantitative estimates take the form of precise L1--L∞-smoothing effects and absolute bounds, and their proofs are based on the interplay between a dual formulation of the problem and estimates on the Green function of -L and I-L. In the linear case m=1, it is well-known that the L1--L∞-smoothing effect, or ultracontractivity, is equivalent to Nash inequalities. This is also equivalent to heat kernel estimates, which imply the Green function estimates that represent a key ingredient in our techniques. We establish a similar scenario in the nonlinear setting m>1. First, we can show that operators for which ultracontractivity holds, also provide L1--L∞-smoothing effects in the nonlinear case. The converse implication is not true in general. A counterexample is given by 0-order L\'evy operators like -L=I-J. They do not regularize when m=1, but we show that surprisingly enough they do so when m>1, due to the convex nonlinearity. This reveals a striking property of nonlinear equations: the nonlinearity allows for better regularizing properties, almost independently of the linear operator. Finally, we show that smoothing effects, both linear and nonlinear, imply families of inequalities of Gagliardo-Nirenberg-Sobolev type, and we explore equivalences both in the linear and nonlinear settings through the application of the Moser iteration.

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