The arithmetic geometry of AdS2 and its continuum limit

Abstract

According to the 't Hooft-Susskind holography, the black hole entropy,SBH, is carried by the chaotic microscopic degrees of freedom, which live in the near horizon region and have a Hilbert space of states of finite dimension d=(SBH). In previous work we have proposed that the near horizon geometry, when the microscopic degrees of freedom can be resolved, can be described by the AdS2[ZN] discrete, finite and random geometry, where N SBH. It has been constructed by purely arithmetic and group theoretical methods in order to explain, in a direct way, the finiteness of the entropy, SBH. What has been left as an open problem is how the smooth AdS2 geometry can be recovered, in the limit when N∞. In the present article we solve this problem, by showing that the discrete and finite AdS2[ZN] geometry can be embedded in a family of finite geometries, AdS2M[ZN], where M is another integer. This family can be constructed by an appropriate toroidal compactification and discretization of the ambient (2+1)-dimensional Minkowski space-time. In this construction N and M can be understood as "infrared" and "ultraviolet" cutoffs respectively. The above construction enables us to obtain the continuum limit of the AdS2M[ZN] discrete and finite geometry, by taking both N and M to infinity in a specific correlated way, following a reverse process: Firstly, by recovering the continuous, toroidally compactified, AdS2[ZN] geometry by removing the ultraviolet cutoff; secondly, by removing the infrared cutoff in a specific decompactification limit, while keeping the radius of AdS2 finite. It is in this way that we recover the standard non-compact AdS2 continuum space-time. This method can be applied directly to higher-dimensional AdS spacetimes.