Finite time blowup for a supercritical defocusing nonlinear wave system

Abstract

We consider the global regularity problem for defocusing nonlinear wave systems u = (∇ Rm F)(u) on Minkowski spacetime R1+d with d'Alambertian := -∂t2 + Σi=1d ∂xi2, the field u: R1+d Rm is vector-valued, and F: Rm R is a smooth potential which is positive and homogeneous of order p+1 outside of the unit ball, for some p >1. This generalises the scalar defocusing nonlinear wave (NLW) equation, in which m=1 and F(v) = 1p+1 |v|p+1. It is well known that in the energy sub-critical and energy-critical cases when d ≤ 2 or d ≥ 3 and p ≤ 1+4d-2, one has global existence of smooth solutions (for dimensions d ≤ 7 at least) from arbitrary smooth initial data u(0), ∂t u(0). In this paper we study the supercritical case where d = 3 and p > 5. We show that in this case, there exists smooth potential F for some sufficiently large m (in fact we can take m=40), positive and homogeneous of order p+1 outside of the unit ball, and a smooth choice of initial data u(0), ∂t u(0) for which the solution develops a finite time singularity. In fact the solution is discretely self-similar in a backwards light cone. The basic strategy is to first select the mass and energy densities of u, then u itself, and then finally design the potential F in order to solve the required equation. The Nash embedding theorem is used in the second step, explaining the need to take m relatively large.