Insights on entanglement entropy in 1 + 1 dimensional causal sets

Abstract Entanglement entropy in causal sets offers a fundamentally covariant characterisation of quantum field degrees of freedom. A known result in this context is that the degrees of freedom consist of a number of contributions that have continuum-like analogues, in addition to a number of contri...

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Bibliographic Details
Published inClassical and quantum gravity Vol. 39; no. 24; pp. 245004 - 245027
Main Authors Keseman, Théo, Muneesamy, Hans J, Yazdi, Yasaman K
Format Journal Article
LanguageEnglish
Published IOP Publishing 15.12.2022
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Summary:Abstract Entanglement entropy in causal sets offers a fundamentally covariant characterisation of quantum field degrees of freedom. A known result in this context is that the degrees of freedom consist of a number of contributions that have continuum-like analogues, in addition to a number of contributions that do not. The latter exhibit features below the discreteness scale and are excluded from the entanglement entropy using a ‘truncation scheme’. This truncation is necessary to recover the standard spatial area law of entanglement entropy. In this paper we build on previous work on the entanglement entropy of a massless scalar field on a causal set approximated by a 1 + 1D causal diamond in Minkowski spacetime. We present new insights into the truncated contributions, including evidence that they behave as fluctuations and encode features specific to a particular causal set sprinkling. We extend previous results in the massless theory to include Rényi entropies and include new results for the massive theory. We also discuss the implications of our work for the treatment of entanglement entropy in causal sets in more general settings.
Bibliography:CQG-108921.R1
ISSN:0264-9381
1361-6382
DOI:10.1088/1361-6382/ac5fc0