Photon ring structure of rotating regular black holes and no-horizon spacetimes

Abstract

Abstract The Kerr black holes possess a photon region with prograde and retrograde orbits radii, respectively, M ⩽ r p − ⩽ 3 M and 3 M ⩽ r p + ⩽ 4 M , and thereby always cast a closed photon ring or a shadow silhouette for a ⩽ M. For a > M, it is a no-horizon spacetime (naked singularity) wherein prograde orbits spiral into the central singularity, and retrograde orbits produce an arc-like shadow with a dark spot at the center. We compare Kerr black holes’ photon ring structure with those produced by three rotating regular spacetimes, viz Bardeen, Hayward, and nonsingular. These are non-Kerr black hole metrics with an additional deviation parameter of g related to the nonlinear electrodynamics charge. It turns out that for a given a, there exists a critical value of g, g E such that Δ = 0 has no zeros for g > g E, one double zero at r = r E for g = g E, respectively, corresponding to a no-horizon regular spacetime and extremal black hole with degenerate horizon. We demonstrate that, unlike the Kerr naked singularity, no-horizon regular spacetimes can possess closed photon ring when g E < g ⩽ g c, e.g. for a = 0.10M, Bardeen (g E = 0.763 332M < g ⩽ g c = 0.816 792M), Hayward (g E = 1.052 97M < g ⩽ g c = 1.164 846M) and nonsingular (g E = 1.2020M < g ⩽ g c = 1.222 461M) no-horizon spacetimes have closed photon ring. These results confirm that the mere existence of a closed photon ring does not prove that the compact object is necessarily a black hole. The ring circularity deviation observable ΔC for the three no-horizon rotating spacetimes satisfy ΔC ⩽ 0.10 as per the M87* black hole shadow observations. We have also appended the case of Kerr–Newman no-horizon spacetimes (naked singularities) with similar features.