Isospectrality breaking in the Teukolsky formalism

TL;DR

This paper extends the Teukolsky formalism to analyze how modified gravity theories cause isospectrality breaking in black hole quasinormal modes, providing a new method for studying gravitational wave signatures of such theories.

Contribution

It introduces a method to compute quasinormal modes in modified gravity for rotating black holes, extending the Teukolsky formalism and defining parity modes in this context.

Findings

Eigenvalue perturbation shows degeneracy breaking in mode frequencies.

Application to specific modified gravity theories demonstrates the method.

Foundation laid for analyzing isospectrality breaking in rotating black holes.

Abstract

General relativity, though the most successful theory of gravity, has been continuously modified to resolve its incompatibility with quantum mechanics and explain the origin of dark energy or dark matter. One way to test these modified gravity theories is to study the gravitational waves emitted during the ringdown of binary mergers, which consist of quasinormal modes. In several modified gravity theories, the even- and odd-parity gravitational perturbations of non-rotating and slowly rotating black holes have different quasinormal mode frequencies, breaking the isospectrality of general relativity. For black holes with arbitrary spin in modified gravity, there were no avenues to compute quasinormal modes except numerical relativity, until recent extensions of the Teukolsky formalism. In this work, we describe how to use the modified Teukolsky formalism to study isospectrality breaking in modified gravity. We first introduce how definite-parity modes are defined through combinations of Weyl scalars in general relativity, and then, we extend this definition to modified gravity. We then use the eigenvalue perturbation method to show how the degeneracy in quasinormal mode frequencies of different parity is broken in modified gravity. To demonstrate our analysis, we also apply it to some specific modified gravity theories. Our work lays the foundation for studying isospectrality breaking of quasinormal modes in modified gravity for black holes with arbitrary spin.