Entanglement entropy: Holography and renormalization group

We derive a general formula for renormalized entanglement entropy in evendimensional 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 extrinsic counterterms and the use of the replica trickà la Lewkowycz-Maldacena. The boundary counterterm B d 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 entanglement 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.

“…Note that in the general case, for W (0) = 0, W (2) ij kl can be further simplified and rewritten in a more compact form. In particular, we have that 26) or equivalently,…”

Section: Asymptotic Conformal Flatnessmentioning

confidence: 99%

“…For reviews on developments in these two directions, see e.g. [25,26] and [27][28][29], respectively. In more detail, given a state of a quantum system, and a subset A of its degrees of freedom, entanglement between A and its complement A c is quantified by the entanglement entropy S ≡ − Tr A ( A ln A ), with A ≡ Tr A c .…”

Section: Introductionmentioning

confidence: 99%

Renormalized AdS gravity and holographic entanglement entropy of even-dimensional CFTs

Anastasiou

Araya

Güijosa

et al. 2019

“…One also finds a universal sub-leading term in odd-dimensional CFTs but in this case it is finite rather than logarithmic, see e.g. [10] and references therein. The coefficient of the universal term is a function of topological and geometric invariants, such as the Euler density and Weyl invariants constructed from the entangling (hyper)-surface [11,12].…”

Section: Introductionmentioning

confidence: 98%

“…In recent years considerable effort has been devoted to investigating such universal terms in the entanglement entropy of CFTs in arbitrary dimensions (see [9,10] for reviews). What will be important for us is the following general UV behavior of entanglement entropy in even D-dimensional CFTs,…”

Section: Introductionmentioning

confidence: 99%

Entanglement entropy in generalised quantum Lifshitz models

Angel-Ramelli

Puletti

Thorlacius

2019

We compute universal finite corrections to entanglement entropy for generalised quantum Lifshitz models in arbitrary odd spacetime dimensions. These are generalised free field theories with Lifshitz scaling symmetry, where the dynamical critical exponent z equals the number of spatial dimensions d, and which generalise the 2+1-dimensional quantum Lifshitz model to higher dimensions. We analyse two cases: one where the spatial manifold is a d-dimensional sphere and the entanglement entropy is evaluated for a hemisphere, and another where a d-dimensional flat torus is divided into two cylinders. In both examples the finite universal terms in the entanglement entropy are scale invariant and depend on the compactification radius of the scalar field.

“…where T = 2πα/β, Vol(S d−1 ) = 2π d/2 /Γ(d/2), and a * d is the generalized central charge given by [76] 20) with A d the A-type trace anomaly of the stress tensor (see Ref. [77] for conventions) and Z(S d ) the regularized vacuum partition function of the CFT placed on a unit d-dimensional sphere (see Ref.…”

Section: Strongly Coupled Theoriesmentioning

confidence: 99%

Localized thermal states and negative energy

Rosso

2019

We construct localized states defined in a ball or the half-space of a conformal field theory (CFT) in Minkowski that are thermal with respect to the local modular flow. We compute their energy density at arbitrary temperature for a variety of CFTs, and find values for which it is negative and divergent at the boundary. Despite this singular behavior we show that the energy measured by an observer is consistent with the bounds present in the literature. For holographic CFTs these states are captured by hyperbolic black holes in anti-de Sitter, where the negative energy in field theory amounts to the well known negative mass of the black hole. As a byproduct, we show that the Casini-Huerta-Myers proof of the Ryu-Takayangi holographic entanglement formula for the vacuum reduced to a ball can be naturally extended to include half-space regions.