📝 SummarXiv

Abstract

Uniqueness (up to isometries) and existence of limits are analyzed in the context of Cheeger-Gromov convergence of spacetimes. To face the non-compactness of the vector isometry group in the semi-Riemanian setting, standard \em{pointed} convergence is strenghtened to \em{anchored} convergence (which requires the convergence of a timelike direction in the Lorenzian case). Then, a local isometry between the neighborhoods of the basepoints is found, and extended globally under geodesic completeness and simple connectedness. In spacetimes, by using Cauchy temporal functions as both strengthenings of the anchor and tools to ``Wick rotate'' metrics, a new notion of convergence for globally hyperbolic spacetimes (including the case of timelike boundaries) is introduced. The machinery of Riemannian Cheeger-Gromov theory becomes applicable after revisiting the tools related to time functions and studying their connections with Sormani-Vega null distance. In particular, several results with interest on its own right are obtained such as: time functions are locally Lipschitz up to rescaling, global and local characterizations of $h$-steep functions, independence of steepness and $h$-steepness for temporal functions, compatibility of both conditions for Cauchy temporal functions, and the stability of the latter.