Abstract
In the AdS/CFT correspondence, the entanglement entropy of subregions in the boundary CFT is conjectured to be dual to the area of a bulk extremal surface at leading order in GN in the holographic limit. Under this dictionary, distantly separated regions in the CFT vacuum state have zero mutual information at leading order, and only attain nonzero mutual information at this order when they lie close enough to develop significant classical and quantum correlations. Previously, the separation at which this phase transition occurs for equal-size ball-shaped regions centered at antipodal points on the boundary was known analytically only in 3 spacetime dimensions. Inspired by recent explorations of general relativity at large-d, we compute the separation at which the phase transition occurs analytically in the limit of infinitely many spacetime dimensions, and find that distant regions cannot develop large correlations without collectively occupying the entire volume of the boundary theory. We interpret this result as illustrating the spatial decoupling of holographic correlations in the large-d limit, and provide intuition for this phenomenon using results from quantum information theory. We also compute the phase transition separation numerically for a range of bulk spacetime dimensions from 4 to 21, where analytic results are intractable but numerical results provide insight into the dimension-dependence of holographic correlations. For bulk dimensions above 5, our exact numerical results are well approximated analytically by working to next-to-leading order in the large-d expansion.
Highlights
In concrete realizations of the AdS/CFT correspondence, this expression has been argued to follow from path integral arguments [4, 5], with the O(1) corrections having been computed in [6]
The primary motivation for our analysis was to understand how the spatial correlation of spacetime regions in a quantum field theory depends on the dimension of the spacetime
We focused our attention on holographic field theories where the difficult computation of the entanglement entropy of a given region in the boundary CFTd can be mapped to the simpler problem of computing the area of the smallest-area extremal surface in AdSd+1 anchored to the boundary of the region via the HRRT formula (1.1)
Summary
We derive the parameters of the mutual information phase transition in vacuum AdSd+1 (i) analytically in the limit of large d, and (ii) numerically for intermediate dimensions 3 ≤ d ≤ 20. Our first step will be to introduce a system of coordinates in which the differential equation satisfied by extremal surfaces homologous to these regions takes a simple form. We study this equation analytically in a large-d expansion to find the quantitative behavior of the phase transition in the large-d limit, and give numerical results for dimensions d = 3 through d = 20 where analytical results are intractable. We find that in the large-d limit, the boundary separation at which antipodal regions develop nonzero mutual information at order G−N1 vanishes as 1/(d − 2) in the usual spherical metric for the boundary
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