Related papers: Thermal nature of the causal diamond horizon: A hidden property of the inertial propagator

Thermal nature of the causal diamond horizon: A hidden property of the inertial propagator

URL: http://arxiv.org/abs/2508.16880v1
Date: Sat, 23 Aug 2025 02:45:16 GMT
Title: Thermal nature of the causal diamond horizon: A hidden property of the inertial propagator
Authors: Nada Eissa, Carlos R. Ordóñez, Gustavo Valdivia-Mera,
Abstract summary: We develop a method to uncover the hidden thermal properties of the inertial Feynman propagator in Minkowski spacetime.<n>Future-directed propagation across causal horizons can be consistently interpreted.<n>We find that the ratio of emission and absorption processes reproduces the characteristic Boltzmann factor of a thermal ensemble.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Inspired by the novel idea proposed by T.~Padmanabhan in Phys. Rev. D 100, 045024 (2019), we develop a method to uncover the hidden thermal properties of the inertial Feynman propagator in Minkowski spacetime in a causally consistent manner. This, in turn, enables a coherent interpretation based on future-directed propagation. In this method, the Fourier transform is implemented following the convention used in the analysis of vacuum fluctuations. As a result, future-directed propagation across causal horizons can be consistently interpreted, from the perspective of an observer confined to a causally disconnected region, as the emission of scalar quanta at the past horizon and their absorption at the future horizon. Furthermore, we find that the ratio of emission and absorption processes reproduces the characteristic Boltzmann factor of a thermal ensemble. We first apply this analysis to the right Rindler wedge, recovering the well-known Unruh temperature, $T = a/(2\pi)$. We then extend the analysis to a causal diamond of length $2\alpha$, performing a meticulous analysis of the near-horizon geometry and thereby obtaining the temperature associated with the thermal behavior of the Minkowski vacuum as perceived by an observer with finite lifetime $2\alpha$. Our results demonstrate that thermality can emerge directly from causal structure, independently of acceleration or gravity, with causal diamonds encoding intrinsic thermodynamic behavior in quantum field theory.

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