Statistical Entropy of a BTZ Black Hole from Loop Quantum Gravity

Abstract

We compute the statistical entropy of a BTZ black hole in the context of three-dimensional Euclidean loop quantum gravity with a cosmological constant . As in the four-dimensional case, a quantum state of the black hole is characterized by a spin network state. Now however, the underlying colored graph lives in a two-dimensional spacelike surface , and some of its links cross the black hole horizon, which is viewed as a circular boundary of . Each link crossing the horizon is colored by a spin j (at the kinematical level), and the length L of the horizon is given by the sum L=Σ L of the fundamental length contributions L carried by the spins j of the links . We propose an estimation for the number NBTZ(L,) of the Euclidean BTZ black hole microstates (defined on a fixed graph ) based on an analytic continuation from the case >0 to the case <0. In our model, we show that NBTZ(L,) reproduces the Bekenstein-Hawking entropy in the classical limit. This asymptotic behavior is independent of the choice of the graph provided that the condition L=Σ L is satisfied, as it should be in three-dimensional quantum gravity.