在重力路径积分的渐变轮廓上

IF 5.3 2区物理与天体物理 Q1 Physics and Astronomy

Physical Review D Pub Date : 2025-03-19 DOI:10.1103/physrevd.111.066014

Batoul Banihashemi, Ted Jacobson

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引用次数: 0

摘要

与其他规范场理论类似，引力路径积分通常是用协变作用来实现的，但引力的情况有很多重要的不同之处。一个关键的区别是被积函数有一个本质的奇点，它发生在时空度规退化的零衰减处。施加局部时间再参数化约束所需的延时积分轮廓必须从−∞运行到+∞，但不能经过零。这就提出了一个问题：对于一个应用程序，比如配分函数，应该在哪里施加约束，什么是正确的积分轮廓，为什么？我们从不涉及本质奇点的化简相空间路径积分开始研究这个问题。我们观察到，如果要在渐变前对动量进行积分，为了得到位形空间路径积分，渐变轮廓线应该在复渐变平面中经过原点以下。这个轮廓也符合量子场涨落振幅具有通常的短距离真空形式的要求，并且符合从洛伦兹路径积分中获得贝肯斯坦-霍金视界熵的要求。2025年由美国物理学会出版

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On the lapse contour in the gravitational path integral

The gravitational path integral is usually implemented with a covariant action by analogy with other gauge field theories, but the gravitational case is different in important ways. A key difference is that the integrand has an essential singularity, which occurs at zero lapse where the spacetime metric degenerates. The lapse integration contour required to impose the local time reparametrization constraints must run from −∞ to +∞, yet must not pass through zero. This raises the question: for an application—such as a partition function—where the constraints should be imposed, what is the correct integration contour, and why? We study that question by starting with the reduced phase space path integral, which involves no essential singularity. We observe that if the momenta are to be integrated before the lapse, to obtain a configuration space path integral, the lapse contour should pass below the origin in the complex lapse plane. This contour is also consistent with the requirement that quantum field fluctuation amplitudes have the usual short distance vacuum form, and with obtaining the Bekenstein-Hawking horizon entropy from a Lorentzian path integral.

Published by the American Physical Society

2025

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来源期刊

Physical Review D 物理-天文与天体物理

CiteScore

9.20

自引率

36.00%

发文量

审稿时长

2 months

期刊介绍： Physical Review D (PRD) is a leading journal in elementary particle physics, field theory, gravitation, and cosmology and is one of the top-cited journals in high-energy physics. PRD covers experimental and theoretical results in all aspects of particle physics, field theory, gravitation and cosmology, including: Particle physics experiments, Electroweak interactions, Strong interactions, Lattice field theories, lattice QCD, Beyond the standard model physics, Phenomenological aspects of field theory, general methods, Gravity, cosmology, cosmic rays, Astrophysics and astroparticle physics, General relativity, Formal aspects of field theory, field theory in curved space, String theory, quantum gravity, gauge/gravity duality.