Lower-Dimensional Black Hole Chemistry

Abstract

The connection between black hole thermodynamics and chemistry is extended to the lower-dimensional regime by considering the rotating and charged BTZ metric in the (2+1)-D and a (1+1)-D limits of Einstein gravity. The Smarr relation is naturally upheld in both BTZ cases, where those with Q 0 violate the Reverse Isoperimetric Inequality and are thus superentropic. The inequality can be maintained, however, with the addition of a new thermodynamic work term associated with the mass renormalization scale. The D→ 0 limit of a generic D+2-dimensional Einstein gravity theory is also considered to derive the Smarr and Komar relations, although the opposite sign definitions of the cosmological constant and thermodynamic pressure from the D>2 cases must be adopted in order to satisfy the relation. The requirement of positive entropy implies a lower bound on the mass of a (1+1)-D black hole. Promoting an associated constant of integration to a thermodynamic variable allows one to define a "rotation" in one spatial dimension. Neither the D=3 nor the D → 2 black holes exhibit any interesting phase behaviour.