English

An intrinsic hyperboloid approach for Einstein Klein-Gordon equations

Analysis of PDEs 2016-07-07 v1 General Relativity and Quantum Cosmology Differential Geometry

Abstract

In [7] Klainerman introduced the hyperboloidal method to prove the global existence results for nonlinear Klein-Gordon equations by using commuting vector fields. In this paper, we extend the hyperboloidal method from Minkowski space to Lorentzian spacetimes. This approach is developed in [14] for proving, under the maximal foliation gauge, the global nonlinear stability of Minkowski space for Einstein equations with massive scalar fields, which states that, the sufficiently small data in a compact domain, surrounded by a Schwarzschild metric, leads to a unique, globally hyperbolic, smooth and geodesically complete solution to the Einstein Klein-Gordon system. In this paper, we set up the geometric framework of the intrinsic hyperboloid approach in the curved spacetime. By performing a thorough geometric comparison between the radial normal vector field induced by the intrinsic hyperboloids and the canonical \pr\p_r, we manage to control the hyperboloids when they are close to their asymptote, which is a light cone in the Schwarzschild zone. By using such geometric information, we not only obtain the crucial boundary information for running the energy method in [14], but also prove that the intrinsic geometric quantities including the Hawking mass all converge to their Schwarzschild values when approaching the asymptote.

Keywords

Cite

@article{arxiv.1607.01466,
  title  = {An intrinsic hyperboloid approach for Einstein Klein-Gordon equations},
  author = {Qian Wang},
  journal= {arXiv preprint arXiv:1607.01466},
  year   = {2016}
}
R2 v1 2026-06-22T14:46:36.559Z