Fine properties of solutions to the Cauchy problem for a Fast Diffusion Equation with Caffarelli-Kohn-Nirenberg weights

Abstract

We investigate fine global properties of nonnegative, integrable solutions to the Cauchy problem for the Fast Diffusion Equation with weights (WFDE) ut=|x|γdiv(|x|-β∇ um) posed on (0,+∞)×Rd, with d 3, in the so-called good fast diffusion range mc<m<1, within the range of parameters γ, β, optimal for the validity of the so-called Caffarelli-Kohn-Nirenberg inequalities. It is a natural question to ask in which sense such solutions behave like the Barenblatt B (fundamental solution): for instance, asymptotic convergence, i.e. \|u(t)-B(t)\| Lp(Rd)[]t∞0, is well known for all 1 p ∞, while only few partial results tackle a finer analysis of the tail behaviour. We characterize the maximal set of data X⊂ L1+(Rd) that produces solutions which are pointwise trapped between two Barenblatt (Global Harnack Principle), and uniformly converge in relative error (UREC), i.e. d∞(u(t))=\|u(t)/B(t)-1\| L∞(Rd)[]t∞0. Such characterization is in terms of an integral condition on u(t=0). To the best of our knowledge, analogous issues for the linear heat equation m=1, do not possess such clear answers. Our characterization is also new for the classical, non-weighted, FDE. We are able to provide minimal rates of convergence to B in different norms. Such rates are almost optimal in the non weighted case, and become optimal for radial solutions. To complete the panorama, we show that solutions with data in L1+(Rd), preserve the same "fat" spatial tail for all times, hence UREC fails.