Analytic study of self-gravitating polytropic spheres with light rings

Abstract

Ultra-compact objects describe horizonless solutions of the Einstein field equations which, like black-hole spacetimes, possess null circular geodesics (closed light rings). We study analytically the physical properties of spherically symmetric ultra-compact isotropic fluid spheres with a polytropic equation of state. It is shown that these spatially regular horizonless spacetimes are generally characterized by two light rings \rinnerγ,routerγ\ with the property C(rinnerγ)≤ C(routerγ), where C m(r)/r is the dimensionless compactness parameter of the self-gravitating matter configurations. In particular, we prove that, while black-hole spacetimes are characterized by the lower bound C(rinnerγ)≥1/3, horizonless ultra-compact objects may be characterized by the opposite dimensionless relation C(rinnerγ)≤1/4. Our results provide a simple analytical explanation for the interesting numerical results that have recently presented by Novotn\'y, Hlad\'ik, and Stuchl\'ik [Phys. Rev. D 95, 043009 (2017)].