Semiclassical (QFT) and Quantum (String) Rotating Black Holes and their Evaporation: New Results

TL;DR

This paper combines quantum field theory and string theory to analyze Kerr-Newman black holes, revealing new emission behaviors, bounds, phase transitions, and a revised entropy formula, especially at extremal conditions.

Contribution

It introduces a comprehensive framework using the string analogue model to study black hole evaporation, uncovering new phase transitions and bounds in the quantum string regime.

Findings

Black hole emission at Hawking temperature in early evaporation

Discovery of a Hagedorn transition at last stages of evaporation

New extremal black hole phase transition with altered entropy

Abstract

Combination of both quantum field theory (QFT) and string theory in curved backgrounds in a consistent framework, the string analogue model, allows us to provide a full picture of the Kerr-Newman black hole and its evaporation going beyond the current picture. We compute the quantum emission cross section of strings by a Kerr-Newmann black hole (KNbh). It shows the black hole emission at the Hawking temperature T_{sem} in the early evaporation and the new string emission featuring a Hagedorn transition into a string state of temperature T_ s at the last stages. New bounds on the angular momentum J and charge Q emerge in the quantum string regime. The last state of evaporation of a semiclassical KNbh is a string state of temperature T_s, mass M_s, J = 0 = Q, decaying as a quantum string into all kinds of particles.(There is naturally, no loss of information, (no paradox at all)). We compute the microscopic string entropy S_s(m, j) of mass m and spin mode j. (Besides the usual transition at T_s), we find for high j, (extremal string states) a new phase transition at a temperature T_{sj} higher than T_s. We find a new formula for the Kerr black hole entropy S_{sem}, as a function of the usual Bekenstein-Hawking entropy . For high angular momentum, (extremal J = GM^2/c), a gravitational phase transition operates and the whole entropy S_{sem} is drastically different from the Bekenstein-Hawking entropy. This new extremal black hole transition occurs at a temperature T_{sem J} higher than the Hawking temperature T_{sem}.