The variational approach to s-fractional heat flows and the limit cases s 0+ and s 1-

Abstract

This paper deals with the limit cases for s-fractional heat flows in a cylindrical domain, with homogeneous Dirichlet boundary conditions, as s 0+ and s 1-\,. To this purpose, we describe the fractional heat flows as minimizing movements of the corresponding Gagliardo seminorms, with respect to the L2 metric. First, we provide an abstract stability result for minimizing movements in Hilbert spaces, with respect to a sequence of -converging uniformly λ-convex energy functionals. Then, we provide the -convergence analysis of the s-Gagliardo seminorms as s 0+ and s 1-\,, and apply the general stability result to such specific cases. As a consequence, we prove that s-fractional heat flows (suitably scaled in time) converge to the standard heat flow as s 1-, and to a degenerate ODE type flow as s 0+\,. Moreover, looking at the next order term in the asymptotic expansion of the s-fractional Gagliardo seminorm, we show that suitably forced s-fractional heat flows converge, as s 0+\,, to the parabolic flow of an energy functional that can be seen as a sort of renormalized 0-Gagliardo seminorm: the resulting parabolic equation involves the first variation of such an energy, that can be understood as a zero (or logarithmic) Laplacian.