Proca Stars: gravitating Bose-Einstein condensates of massive spin 1 particles

TL;DR

This paper demonstrates that massive spin 1 particles can form stable, gravitating Bose-Einstein condensates called Proca stars, which are similar to scalar boson stars but involve vector fields and have unique properties.

Contribution

It introduces and analyzes Proca stars, a new class of gravitating solitons formed by massive vector fields, expanding the understanding of boson star-like objects.

Findings

Proca stars exist with both spherical and axial symmetry.

They have a maximum mass slightly larger than scalar boson stars.

Some solutions are perturbatively stable, indicating potential physical relevance.

Abstract

We establish that massive complex Abelian vector fields (mass $\mu$) can form gravitating solitons, when minimally coupled to Einstein's gravity. Such Proca stars (PSs) have a stationary, everywhere regular and asymptotically flat geometry. The Proca field, however, possesses a harmonic time dependence (frequency $w$), realizing Wheeler's concept of geons for an Abelian spin 1 field. We obtain PSs with both a spherically symmetric (static) and an axially symmetric (stationary) line element. The latter form a countable number of families labelled by an integer $m\in \mathbb{Z}^+$. PSs, like (scalar) boson stars, carry a conserved Noether charge, and are akin to the latter in many ways. In particular, both types of stars exist for a limited range of frequencies and there is a maximal ADM mass, $M_{max}$, attained for an intermediate frequency. For spherically symmetric PSs (rotating PSs with $m=1,2,3$), $M_{max}\simeq 1.058 M_{Pl}^2/\mu$ ($M_{max}\simeq 1.568,\, 2.337, \, 3.247 \, M_{Pl}^2/\mu$), slightly larger values than those for (mini-)boson stars. We establish perturbative stability for a subset of solutions in the spherical case and anticipate a similar conclusion for fundamental modes in the rotating case. The discovery of PSs opens many avenues of research, reconsidering five decades of work on (scalar) boson stars, in particular as possible dark matter candidates.