Abstract
Quantum extremal surfaces (QES), codimension-2 spacelike regions which extremize the generalized entropy of a gravity-matter system, play a key role in the study of the black hole information problem. The thermodynamics of QESs, however, has been largely unexplored, as a proper interpretation requires a detailed understanding of backreaction due to quantum fields. We investigate this problem in semi-classical Jackiw-Teitelboim (JT) gravity, where the spacetime is the eternal two-dimensional Anti-de Sitter (AdS2) black hole, Hawking radiation is described by a conformal field theory with central charge c, and backreaction effects may be analyzed exactly. We show the Wald entropy of the semi-classical JT theory entirely encapsulates the generalized entropy — including time-dependent von Neumann entropy contributions — whose extremization leads to a QES lying just outside of the black hole horizon. Consequently, the QES defines a Rindler wedge nested inside the enveloping black hole. We use covariant phase space techniques on a time-reflection symmetric slice to derive a Smarr relation and first law of nested Rindler wedge thermodynamics, regularized using local counterterms, and intrinsically including semi-classical effects. Moreover, in the microcanonical ensemble the semi-classical first law implies the generalized entropy of the QES is stationary at fixed energy. Thus, the thermodynamics of the nested Rindler wedge is equivalent to the thermodynamics of the QES in the microcanonical ensemble.
Highlights
Classical gravity posits black holes obey a set of mechanical laws formally reminiscent of the laws of thermodynamics, where the horizon area is interpreted as a thermodynamic entropy obeying a second law
Before moving on to the section where we study the thermodynamics of the Quantum extremal surfaces (QES), let us point out the generalized entropy in the Boulware state is extremized by a quantum extremal surface
Extremizing the generalized entropy along the time slice t = tB led to a crucial insight: the appearance of a quantum extremal surface that lies just outside of the black hole horizon, consistent with previous investigations on the black hole information paradox in eternal backgrounds, e.g., [46, 50, 51]
Summary
Classical gravity posits black holes obey a set of mechanical laws formally reminiscent of the laws of thermodynamics, where the horizon area is interpreted as a thermodynamic entropy obeying a second law. While this study should hold for more realistic theories of gravity, we use the remarkable simplicity of the semi-classical JT model to our advantage where we can solve everything analytically In this context the classical “area” term is given by the value of the dilaton evaluated at X, while the bulk von Neumann entropy is quantified by an auxiliary field used to localize the Polyakov action, and is understood to represent conformal matter fields living in an eternal AdS2 black hole background. In appendix E we provide a heuristic argument for the generalized second law
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
