Natural Cutoffs effect on Charged Rotating TeV-Scale Black Hole Thermodynamics

TL;DR

This paper investigates how quantum gravity-induced minimal length, momentum, and maximal momentum cutoffs influence the thermodynamics of charged rotating TeV-scale black holes, including effects like frame dragging and Sagnac.

Contribution

It introduces a novel analysis of black hole thermodynamics incorporating quantum gravity cutoffs in a large extra dimensions context, focusing on rotation and charge effects.

Findings

Minimal length and momentum alter black hole temperature and entropy.

Angular momentum and charge significantly impact thermodynamic behavior.

Frame dragging and Sagnac effects are relevant for micro black holes.

Abstract

We study the thermodynamics of charged rotating black hole in large extra dimensions scenario where quantum gravity effects are taken into account. We consider the effects of minimal length, minimal momentum, and maximal momentum as natural cutoffs on the thermodynamics of charged rotating TeV-scale black holes. In this framework the effect of the angular momentum and charge on the thermodynamics of the black hole are discussed. We focus also on frame dragging and Sagnac effect of the micro black holes.