Abstract
We derive a general formula for renormalized entanglement entropy in even- dimensional CFTs holographically dual to Einstein gravity in one dimension higher. In order to renormalize, we adapt the Kounterterm method to asymptotically locally AdS manifolds with conical singularities. On the gravity side, the computation considers extrin- sic counterterms and the use of the replica trick à la Lewkowycz-Maldacena. The boundary counterterm Bd is shown to satisfy a key property, in direct analogy to the Euler density: when evaluated on a conically singular manifold, it decomposes into a regular part plus a codimension-2 version of itself located at the conical singularity. The renormalized entropy thus obtained is shown to correspond to the universal part of the holographic entangle- ment entropy, which for spherical entangling surfaces is proportional to the central charge a that is the subject of the a-theorem. We also review and elucidate various aspects of the Kounterterm approach, including in particular its full compatibility with the Dirichlet condition for the metric at the conformal boundary, that is of standard use in holography.
Highlights
Entanglement, whose usefulness as an experimental resource has long been understood by the quantum information community, has deeply impacted theoretical high energy and gravity research in the past 15 years
This is the only power-law divergence that appears in the case of AdS5/CFT4, so for 4D conformal field theory (CFT), we have shown here that the renormalization procedure based on extrinsic counterterms works in full generality
We have elucidated two important points regarding the applicability of the Kounterterm prescription and its relation to the standard method of holographic renormalization [65, 68, 69]
Summary
Entanglement, whose usefulness as an experimental resource has long been understood by the quantum information community, has deeply impacted theoretical high energy and gravity research in the past 15 years. It sheds valuable light on the dynamics of quantum field theories. In the context of holographic duality [16,17,18], a very profound link has been discovered between entanglement and gravity. This connection serves as a calculational tool for deducing the pattern of entanglement in certain strongly-coupled field theories [19,20,21], and enables the emergence of a dynamical spacetime from degrees of freedom living on a lower-dimensional rigid geometry [22,23,24]. For reviews on developments in these two directions, see e.g. [25, 26] and [27,28,29], respectively
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
