Exterior Energy Bounds for the Critical Wave Equation Close to the Ground State
Abstract
By definition, the exterior asymptotic energy of a solution to a wave equation on R1+N is the sum of the limits as t→±∞ of the energy in the the exterior {|x|>|t|} of the wave cone. In our previous work Duyckaerts et al. (J Eur Math Soc 14(5):1389-1454, 2012), we have proved that the exterior asymptotic energy of a solution of the linear wave equation in odd space dimension N is bounded from below by the conserved energy of the solution. In this article, we study the analogous problem for the linear wave equation with a potential *∂t2u+LWu=0,LW:=-Δ-N+2N-2W4N-2obtained by linearizing the energy critical wave equation at the ground-state solution W, still in odd space dimension. This equation admits nonzero solutions of the form A+tB, where LWA=LWB=0 with vanishing asymptotic exterior energy. We prove that the exterior energy of a solution of (∗) is bounded from below by the energy of the projection of the initial data on the orthogonal complement of the space of initial data corresponding to these solutions. This will be used in a subsequent paper to prove soliton resolution for the energy-critical wave equation with radial data in all odd space dimensions. We also prove analogous results for the linearization of the energy-critical wave equation around a Lorentz transform of W, and give applications to the dynamics of the nonlinear equation close to the ground state in space dimensions 3 and 5.
- Publication:
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Communications in Mathematical Physics
- Pub Date:
- November 2020
- DOI:
- 10.1007/s00220-020-03757-6
- arXiv:
- arXiv:1912.07658
- Bibcode:
- 2020CMaPh.379.1113D
- Keywords:
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- Mathematics - Analysis of PDEs
- E-Print:
- doi:10.1007/s00220-020-03757-6