Holographic entanglement entropy and generalized entanglement temperature

Abstract

In this work we study the flow of holographic entanglement entropy in dimensions d ≥ 3 in the gauge/gravity duality set up. We observe that a generalized entanglement temperature Tg can be defined which gives the Hawking temperature TH in the infrared region and leads to a generalized thermodynamics like law E= (d-1d)Tg~SREE, which becomes an exact relation in the entire region of the subsystem size l, including both the infrared (l→∞) as well as the ultraviolet (l→ 0) regions. Furthermore, in the IR limit, Tg produces the Hawking temperature TH along with some correction terms which bears the signature of short distance correlations along the entangling surface. Moreover, for d≥ 3, the IR limit of the renormalized holographic entanglement entropy gives the thermal entropy of the black hole as the leading term, however, does not have a logarithmic correction to the leading term unlike the BTZ black hole (d=2) case. The generalized entanglement temperature Tg also firmly captures the quantum mechanical to thermal crossover in the dual field theory at a critical value lc of the subsystem size in the boundary which we graphically represent for AdS3+1 and AdS4+1 black holes. We observe that this critical value lc where the crossover takes place decreases with increase in the dimension of the spacetime.