Instantaneous shrinking and single point extinction for viscous Hamilton-Jacobi equations with fast diffusion

Abstract

For a large class of non-negative initial data, the solutions to the quasilinear viscous Hamilton-Jacobi equation ∂\t u-\p u+|∇ u|q=0 in (0,∞)×N are known to vanish identically after a finite time when 2N/(N+1) p ≤ 2 and q∈(0,p-1). Further properties of this extinction phenomenon are established herein: instantaneous shrinking of the support is shown to take place if the initial condition u\0 decays sufficiently rapidly as |x|∞, that is, for each t 0, the positivity set of u(t) is a bounded subset of N even if u\0 0 in N. This decay condition on u\0 is also shown to be optimal by proving that the positivity set of any solution emanating from a positive initial condition decaying at a slower rate as |x|∞ is the whole N for all times. The time evolution of the positivity set is also studied: on the one hand, it is included in a fixed ball for all times if it is initially bounded (localization). On the other hand, it converges to a single point at the extinction time for a class of radially symmetric initial data, a phenomenon referred to as single point extinction. This behavior is in sharp contrast with what happens when q ranges in [p-1,p/2) and p∈ (2N/(N+1),2] for which we show complete extinction. Instantaneous shrinking and single point extinction take place in particular for the semilinear viscous Hamilton-Jacobi equation when p=2 and q∈ (0,1) and seem to have remained unnoticed.