One-Dimensional Relativistic Self-Gravitating Systems
Abstract
One of the oldest problems in physics is that of calculating the motion of particles under a specified mutual force: the -body problem. Much is known about this problem if the specified force is non-relativistic gravity, and considerable progress has been made by considering the problem in one spatial dimension. Here, I review what is known about the relativistic gravitational -body problem. Reduction to one spatial dimension has the feature of the absence of gravitational radiation, thereby allowing for a clear comparison between the physics of one-dimensional relativistic and non-relativistic self-gravitating systems. After describing how to obtain a relativistic theory of gravity coupled to point particles, I discuss in turn the two-body, three-body, four-body, and -body problems. Quite general exact solutions can be obtained for the two-body problem, unlike the situation in general relativity in three spatial dimensions for which only highly specified solutions exist. The three-body problem exhibits mild forms of chaos, and provides one of the first theoretical settings in which relativistic chaos can be studied. For , other interesting features emerge. Relativistic self-gravitating systems have a number of interesting problems awaiting further investigation, providing us with a new frontier for exploring relativistic many-body systems.
Keywords
Cite
@article{arxiv.2504.06515,
title = {One-Dimensional Relativistic Self-Gravitating Systems},
author = {Robert B. Mann},
journal= {arXiv preprint arXiv:2504.06515},
year = {2025}
}
Comments
85 Pages, invited paper for special issue of Entropy on Statistical Mechanics of Self-gravitating Systems (ed. B. Miller)