Spectral Analysis of Quasinormal Modes of Planck Stars

TL;DR

This paper computes the quasinormal mode spectrum of Planck stars using high-precision spectral methods, revealing unique spectral features that could serve as signatures of quantum gravity effects in black hole models.

Contribution

It introduces a spectral analysis of QNMs for Planck stars within scale-dependent gravity, uncovering novel spectral features missed by previous methods.

Findings

Detection of fundamental and overtone modes with spectral methods

Identification of a Martini glass spectral morphology

Discovery of isolated overdamped modes with large frequency gaps

Abstract

We investigate the quasinormal modes (QNMs) of Planck stars within the framework of scale-dependent gravity (SDG). In our setup, the running parameter $\alpha$ is fixed to a negative value by matching the effective Newtonian potential to the one-loop EFT result. As a consequence, the associated running Newton coupling does not realise the ultraviolet fixed point of asymptotically safe gravity, and the geometry should be interpreted as an SDG-inspired effective metric rather than a realisation of asymptotically safe gravity itself. We focus on the resulting renormalisation-group-improved Schwarzschild metric, which naturally yields a finite-size Planck-density core. Building on this background, we compute the QNM spectrum for scalar, electromagnetic, and gravitational perturbations using the Spectral Method (SM). This approach, known for its superior accuracy over high-order WKB schemes, enables the detection of fundamental modes, large families of overtones, and purely imaginary overdamped modes that are entirely missed in previous analysis. Our results reveal a robust Martini glass morphology of the oscillatory spectrum across perturbation sectors, nearly equally spaced overdamped modes with characteristic anomalous gaps, and the emergence, in the gravitational sector, of isolated overdamped modes separated from the main sequence by exceptionally large frequency intervals. These features, resolved here for the first time in the Planck-star context, underscore the importance of high-precision spectral techniques in probing subtle signatures of quantum-gravity-inspired black hole models.