The Case Against Smooth Null Infinity I: Heuristics and Counter-Examples

Abstract

This paper initiates a series of works dedicated to the rigorous study of the precise structure of gravitational radiation near infinity. We begin with a brief review of an argument due to Christodoulou [1] stating that Penrose's proposal of smooth conformal compactification of spacetime (or smooth null infinity) fails to accurately capture the structure of gravitational radiation emitted by N infalling masses coming from past timelike infinity i-. Modelling gravitational radiation by scalar radiation, we then take a first step towards a rigorous, fully general relativistic understanding of the non-smoothness of null infinity by constructing solutions to the spherically symmetric Einstein-Scalar field equations. Our constructions are motivated by Christodoulou's argument: They arise dynamically from polynomially decaying boundary data, rφ t-1 as t-∞, on a timelike hypersurface (to be thought of as the surface of a star) and the no incoming radiation condition, r∂vφ=0, on past null infinity I-. We show that if the initial Hawking mass at i- is non-zero, then, in accordance with the non-smoothness of I+, ∂v(rφ) satisfies the following asymptotic expansion near I+ for some constant C≠ 0: ∂v(rφ)=Cr-3 r+ O(r-3). We also show that the same logarithmic terms appear in the linear theory, i.e. when considering the spherically symmetric linear wave equation on a fixed Schwarzschild background. As a corollary, we can apply our results to the scattering problem on Schwarzschild: Putting smooth, compactly supported scattering data for the wave equation on I- and on H-, we find that the asymptotic expansion of ∂v(rφ) near I+ generically contains logarithmic terms at second order, i.e. at order r-4 r.