Constrained HRT Surfaces and their Entropic Interpretation

Abstract

Consider two boundary subregions A and B that lie in a common boundary Cauchy surface, and consider also the associated HRT surface γB for B. In that context, the constrained HRT surface γA:B can be defined as the codimension-2 bulk surface anchored to A that is obtained by a maximin construction restricted to Cauchy slices containing γB. As a result, γA:B is the union of two pieces, γBA:B and γ BA:B lying respectively in the entanglement wedges of B and its complement B. Unlike the area A(γA) of the HRT surface γA, at least in the semiclassical limit, the area A(γA:B) of γA:B commutes with the area A(γB) of γB. To study the entropic interpretation of A(γA:B), we analyze the R\'enyi entropies of subregion A in a fixed-area state of subregion B. We use the gravitational path integral to show that the n≈1 R\'enyi entropies are then computed by minimizing A(γA) over spacetimes defined by a boost angle conjugate to A(γB). In the case where the pieces γBA:B and γ BA:B intersect at a constant boost angle, a geometric argument shows that the n≈1 R\'enyi entropy is then given by A(γA:B)4G. We discuss how the n≈1 R\'enyi entropy differs from the von Neumann entropy due to a lack of commutativity of the n1 and G0 limits. We also discuss how the behaviour changes as a function of the width of the fixed-area state. Our results are relevant to some of the issues associated with attempts to use standard random tensor networks to describe time dependent geometries.

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