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arxiv: 2212.10608 · v4 · pith:W34WL3BZnew · submitted 2022-12-20 · ✦ hep-th · gr-qc

Entropy of causal diamond ensembles

classification ✦ hep-th gr-qc
keywords saddleboundarydiamondcausalconstantcosmologicalentropyeuclidean
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We define a canonical ensemble for a gravitational causal diamond by introducing an artificial York boundary inside the diamond with a fixed induced metric and temperature, and evaluate the partition function using a saddle point approximation. For Einstein gravity with zero cosmological constant there is no exact saddle with a horizon, however the portion of the Euclidean diamond enclosed by the boundary arises as an approximate saddle in the high-temperature regime, in which the saddle horizon approaches the boundary. This high-temperature partition function provides a statistical interpretation of the recent calculation of Banks, Draper and Farkas, in which the entropy of causal diamonds is recovered from a boundary term in the on-shell Euclidean action. In contrast, with a positive cosmological constant, as well as in Jackiw-Teitelboim gravity with or without a cosmological constant, an exact saddle exists with a finite boundary temperature, but in these cases the causal diamond is determined by the saddle rather than being selected a priori.

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  1. Quantum Geometry from Area Fluctuations

    hep-th 2026-06 unverdicted novelty 6.0

    Derives a thermal fluctuation formula for causal-diamond boundary area with a linear term of Verlinde-Zurek scaling interpreted as statistical evidence for discrete quanta of geometry.