A test of the conjectured critical black-hole formation -- null geodesic correspondence: The case of self-gravitating scalar fields

Abstract

It has recently been conjectured [A. Ianniccari et al., Phys. Rev. Lett. 133, 081401 (2024)] that there exists a correspondence between the critical threshold of black-hole formation and the stability properties of null circular geodesics in the curved spacetime of the collapsing matter configuration. In the present compact paper we provide a non-trivial test of this intriguing conjecture. In particular, using analytical techniques we study the physical and mathematical properties of self-gravitating scalar field configurations that possess marginally-stable (degenerate) null circular geodesics. We reveal the interesting fact that the analytically calculated critical compactness parameter Canalyticalmaxr\m(r)/r\=6/25, which signals the appearance of the first (marginally-stable) null circular geodesic in the curved spacetime of the self-gravitating scalar fields, agrees quite well (to within 10\%) with the exact compactness parameter Cnumericalt\maxr\m(r)/r\\0.265 which is computed numerically using fully non-linear numerical simulations of the gravitational collapse of scalar fields at the threshold of black-hole formation [here m(r) is the gravitational mass contained within a sphere of radius r].