Hawking radiation of scalar and vector particles from 5D Myers-Perry black holes

TL;DR

This paper investigates Hawking radiation as a quantum tunneling process from a five-dimensional rotating black hole, analyzing scalar and vector particles in different coordinate systems to confirm the temperature's invariance.

Contribution

It provides a detailed analysis of Hawking radiation from 5D Myers-Perry black holes using tunneling methods for scalar and vector particles in multiple coordinate frames.

Findings

Hawking temperature is consistent across coordinate systems.

Tunneling of scalar and vector particles yields the same Hawking temperature.

Coordinate choice does not affect the Hawking temperature calculation.

Abstract

In the present paper we explore the Hawking radiation as a quantum tunneling effect from a rotating 5 dimensional Myers-Perry black hole (5D-MPBH) with two independent angular momentum components. First, we investigate the Hawking temperature by considering the tunneling of massive scalar particles and spin-1 vector particles from the 5D-MPBH in the Painlev\'{e} coordinates and then in the corotating frames. More specifically, we solve the Klein-Gordon and Proca equations by applying the WKB method and Hamilton-Jacobi equation in both cases. Finally, we recover the Hawking temperature and show that coordinates systems do not affect the Hawking temperature.