Two-dimensional Hawking radiation from the AdS/CFT correspondence

TL;DR

This paper uses the AdS/CFT correspondence to derive the Hawking temperature of a 1+1 dimensional black hole, confirming the holographic approach's effectiveness in reproducing black hole radiation properties.

Contribution

It demonstrates how to compute Hawking radiation temperature holographically using an auxiliary Liouville field without solving wave equations in curved spacetime.

Findings

Successfully derived the Hawking temperature holographically.

Verified the correspondence reproduces the correct radiation temperature.

Simplified the calculation of scalar and Dirac field radiation.

Abstract

The AdS/CFT correspondence has been tested through the reproduction of standard results. Following this approach, we use the correspondence to obtain the Hawking temperature of a black hole in 1+1 dimensions. Using an auxiliary Liouville field, the holographic energy-momentum tensor is found and compared with a radiation energy-momentum tensor, verifying that the correspondence gives the correct temperature. The information about the radiated field in the CFT sector is contained in the central charge, whereas in the radiation tensor this information is in the statistical distribution. This result allows to determine the radiation of scalar and Dirac fields easily and without the necessity of solving the corresponding Klein-Gordon or Dirac equation in a curved spacetime. In both cases, the correct temperature was obtained.