Abstract

The Kerr/CFT correspondence is a possible route to gain insight into the quantum theory of gravity in the near-horizon region of a Kerr black hole via a dual holographic conformal field theory (CFT). Predictions of the black hole entropy, scattering cross-section and the quasi normal modes from the dual holographic CFT corroborate this proposed correspondence. More recently, it has been suggested that quantum gravitational effects in the near-horizon region of a black hole may drastically modify the classical general relativistic description, leading to potential observable consequences. In this paper, we study the absorption cross-section and quasi normal modes of a horizonless Kerr-like exotic compact object (ECO) in the dual CFT picture. Our analysis suggests that the near-horizon quantum modifications of the black hole can be understood as finite size and/or finite $N$ effects in the dual CFT. Signature of the near-horizon modification to a black hole geometry manifests itself as delayed echoes in the ringdown (i.e. the postmerger phase) of a binary black hole coalescence. From our dual CFT analysis we show how the length of the circle, on which the dual CFT lives, must be related to the echo time-delay that depends on the position of the near-horizon quantum structure. We further derive the reflectivity of the ECO membrane in terms of the CFT modular parameters, showing that it takes the Boltzmann form.

Highlights

  • Over the past few decades, the quasinormal modes (QNMs) of various black holes and exotic compact objects (ECOs) have been studied extensively [1,2]

  • We study the finite-size effects of the covering space to the thermal two-point function in order to understand the spectrum of the horizonless ECO

  • II we review some of the basic aspects of a Kerr-like ECO and demonstrate how the absorption cross section and the quasi normal modes differ from the Kerr black hole with a classical event horizon

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Summary

INTRODUCTION

Over the past few decades, the quasinormal modes (QNMs) of various black holes and exotic compact objects (ECOs) have been studied extensively [1,2]. For nonextremal Kerr black holes, the realisation of the correspondence was less trivial but it was shown that there is an underlying hidden SLð2; RÞ × SLð2; RÞ present in the dynamics of a probe scalar field close to the horizon (in the low frequency limit) [24] Based on this “hidden conformal symmetry”, and the dual twodimensional CFT living in the near-horizon region of the Kerr black hole, the black hole entropy as well as the absorption cross section of the black hole [24,25] was computed. We demonstrate how the dual field theory living on a finite circle captures the necessary near-horizon modification of a Kerr-like ECO, predicting the QNM spectrum and absorption cross section from the dual field theory which matches with the direct bulk computations. As shown in the Appendix A, we solve the wave equation in near/far-region and match the solutions in the intermediate region (M ≪ rmatch ≪ 1=ω) at some arbitrary position (given as “rmatch”)

Scattering
Quasinormal modes
Hidden conformal symmetry of classical Kerr spacetime
Dual CFT of the Kerr-like ECO
Quasinormal modes spectrum from the dual CFT
CFT interpretation of absorption probability
OBSERVABLE SIGNATURES
DISCUSSION
Far-region solution
Near-horizon solution
Two-point function on the torus
The Cardy formula
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