English

Defining the space in a general spacetime

General Mathematics 2016-03-23 v1

Abstract

A global vector field vv on a "spacetime" differentiable manifold V\mathrm{V}, of dimension N+1N+1, defines a congruence of world lines: the maximal integral curves of vv, or orbits. The associated global space N_v\mathrm{N}\_v is the set of these orbits. A "vv-adapted" chart on V\mathrm{V} is one for which the RN\mathbb{R}^N vector x(xj) (j=1,...,N){\bf x}\equiv (x^j)\ (j=1,...,N) of the "spatial" coordinates remains constant on any orbit ll. We consider non-vanishing vector fields vv that have non-periodic orbits, each of which is a closed set. We prove transversality theorems relevant to such vector fields. Due to these results, it can be considered plausible that, for such a vector field, there exists in the neighborhood of any point XVX\in \mathrm{V} a chart χ\chi that is vv-adapted and "nice", i.e., such that the mapping χˉ:lx\bar{\chi }: l\mapsto {\bf x} is injective --- unless vv has some "pathological" character. This leads us to define a notion of "normal" vector field. For any such vector field, the mappings χˉ\bar{\chi } build an atlas of charts, thus providing N_v\mathrm{N}\_v with a canonical structure of differentiable manifold (when the topology defined on N_v\mathrm{N}\_v is Hausdorff, for which we give a sufficient condition met in important physical situations). Previously, a local space manifold M_F\mathrm{M}\_\mathrm{F} had been associated with any "reference frame" F\mathrm{F}, defined as an equivalence class of charts. We show that, if F\mathrm{F} is made of nice vv-adapted charts, M_F\mathrm{M}\_\mathrm{F} is naturally identified with an open subset of the global space manifold N_v\mathrm{N}\_v.

Keywords

Cite

@article{arxiv.1512.08718,
  title  = {Defining the space in a general spacetime},
  author = {Mayeul Arminjon},
  journal= {arXiv preprint arXiv:1512.08718},
  year   = {2016}
}

Comments

38 pages. v3: version accepted for publication in Int. J. Geom. Meth. Mod. Phys.: stronger statements in Prop. 0 and Prop. 8, and precisions in the abstract, following from referee's suggestions; stronger form of Theorem 5; new examples

R2 v1 2026-06-22T12:19:33.889Z