Entanglement entropy and thermal phase transitions from curvature singularities

Abstract

We study holographic entanglement entropy and revisit thermodynamics and confnement in the dilaton-gravity system. Our analysis focuses on a solvable class of backgrounds that includes AdS and linear dilaton spacetimes as particular cases, with some results extended to general warped metrics. A general lesson is that the behavior of the holographic theory is tied to the bulk curvature singularities. We fnd that a singular background is confning if and only if i) the singularity coincides with a boundary or ii) it is the linear dilaton. In the former case, for which the singularity cuts of spacetime, we demonstrate that both entanglement entropy and thermodynamics exhibit a frst order phase transition. In the linear dilaton case we fnd instead that both entanglement entropy and thermal phase transitions are of second order. Additionally, along the process we thoroughly derive the radion efective action at quadratic order.