Structural aspects of asymptotically safe black holes

Koch, B; Saueressig F.

Abstract

We study the quantum modifications of classical, spherically symmetric Schwarzschild (anti-) de Sitter black holes within quantum Einstein gravity. The quantum effects are incorporated through the running coupling constants G(k) and Lambda(k), computed within the exact renormalization group approach, and a common scale-setting procedure. We find that, in contrast to common intuition, it is actually the cosmological constant that determines the short-distance structure of the RG-improved black hole: in the asymptotic UV the structure of the quantum solutions is universal and given by the classical Schwarzschild-de Sitter solution, entailing a self-similarity between the classical and quantum regime. As a consequence asymptotically safe black holes evaporate completely and no Planck-size remnants are formed. Moreover, the thermodynamic entropy of the critical Nariai black hole is shown to agree with the microstate count based on the effective average action, suggesting that the entropy originates from quantum fluctuations around the mean-field geometry.

Más información

Título según WOS: Structural aspects of asymptotically safe black holes
Título de la Revista: CLASSICAL AND QUANTUM GRAVITY
Volumen: 31
Número: 1
Editorial: IOP PUBLISHING LTD
Fecha de publicación: 2014
Idioma: English
URL: http://stacks.iop.org/0264-9381/31/i=1/a=015006?key=crossref.7c95d92456359ff6f126458d36a07276
DOI:

10.1088/0264-9381/31/1/015006

Notas: ISI