Renormalization-group improved Schwarzschild black hole: shadow, ringdown, and strong cosmic censorship

Abstract

A renormalization-group (RG) improved Schwarzschild-like black hole (BH) is studied here, with a lapse that interpolates between a classical Schwarzschild exterior and a quantum-smoothed interior set by a cutoff scale ξ and an interpolation parameter γ. We work out the horizon structure together with the photon sphere and shadow radius Rsh, set up the scalar, electromagnetic, and Dirac Regge-Wheeler-Zerilli problems in a single treatment, and compute the fundamental and overtone quasinormal modes by sixth-order WKB, cross-checked against time-domain ringdown. For ξ>0 and γ>0 the geometry is regular, with a de Sitter core. Strong Cosmic Censorship (SCC) is examined at the inner Cauchy horizon, which the improved geometry generates without charge or rotation. The quasinormal spectral gap β=|Im\,ω|/κ- stays multipole-independent at the 6\% level and follows βλL/(2κ-). It remains below the de Sitter Christodoulou bound across the parameter range, and the asymptotically flat late-time tail places the geometry in the SCC-respecting class. A thermodynamic analysis identifies a Davies-type phase transition of the outer horizon, with the Schwarzschild TH 1/r+ decay replaced by a bell-curve profile peaking at TH 0.062. A scan of the (ξ,γ) plane gathers the joint behavior of the shadow, the scalar barrier, the SCC ratio, and TH. Set against Bardeen, Hayward, and Bonanno-Reuter BHs at matched perturbation scale, the improved Schwarzschild BH is the most Schwarzschild-like of the regular-BH family, its static shadow radius degenerate with Hayward and Bonanno-Reuter at the percent level. The closing analysis takes up the sparsity of the Hawking flux and the energy-emission rate, both tied to the outer-horizon surface gravity through a single auxiliary function.