A Causal Order for Spacetimes with $C^0$ Lorentzian Metrics: Proof of Compactness of the Space of Causal Curves

TL;DR

This paper introduces a new causal relation $K^+$ for $C^0$ Lorentzian metrics, proving the compactness of the space of causal curves in globally hyperbolic spacetimes, thus generalizing and simplifying causal analysis.

Contribution

It defines a new causal relation $K^+$ and extends causal concepts to $C^0$ metrics, proving compactness of the space of causal curves in this setting.

Findings

Defined $K^+$ causal relation for $C^0$ metrics

Proved compactness of the space of causal curves in globally hyperbolic spacetimes

Simplified causal analysis for low-regularity metrics

Abstract

We recast the tools of ``global causal analysis'' in accord with an approach to the subject animated by two distinctive features: a thoroughgoing reliance on order-theoretic concepts, and a utilization of the Vietoris topology for the space of closed subsets of a compact set. We are led to work with a new causal relation which we call $K^+$, and in terms of it we formulate extended definitions of concepts like causal curve and global hyperbolicity. In particular we prove that, in a spacetime $\M$ which is free of causal cycles, one may define a causal curve simply as a compact connected subset of $\M$ which is linearly ordered by $K^+$. Our definitions all make sense for arbitrary $C^0$ metrics (and even for certain metrics which fail to be invertible in places). Using this feature, we prove for a general $C^0$ metric, the familiar theorem that the space of causal curves between any two compact subsets of a globally hyperbolic spacetime is compact. We feel that our approach, in addition to yielding a more general theorem, simplifies and clarifies the reasoning involved. Our results have application in a recent positive energy theorem, and may also prove useful in the study of topology change. We have tried to make our treatment self-contained by including proofs of all the facts we use which are not widely available in reference works on topology and differential geometry.