位置和动量的微观状态导致引力熵

IF 0.6 Q4 PHYSICS, MULTIDISCIPLINARY

Physics Essays Pub Date : 2022-12-29 DOI:10.4006/0836-1398-35.4.322

Christopher N. Watson

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引用次数: 1

摘要

对黑洞位置的测量受到四种不同方式的限制：黑洞对短波长光子的吸收、引力透镜对几何衍射的干扰、引力红移降低了接近视界的相互作用的分辨率，以及霍金辐射的波长相对较长。这些限制意味着黑洞不能比其史瓦西半径更精确地定位。测量质量和速度的限制意味着黑洞的位置和动量不能同时精确到2 h rs/lP，一个比海森堡不确定性原理更具限制性的值。关于黑洞位置和动量的隐藏信息导致了许多可能的微观状态，而这些微观状态对观察者来说是无法区分的。解释Bekenstein‐Hawking熵的物理意义的一种方法是测量这些微观状态的数量。这种解释允许熵被推广到任何引力场中的物体，因为引力红移增加了物体在所有引力场中位置和动量的不确定性，而不仅仅是黑洞的位置和动量。

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Microstates of position and momentum result in gravitational entropy

Measurements of a black hole’s position are limited in four different ways: Absorption of short-wavelength photons by the black hole, gravitational lensing’s interference with geometric diffraction, gravitational redshift decreasing the resolution of interactions close to the event horizon, and the relatively long wavelength of Hawking radiation. These limitations mean that a black hole cannot be localized more precisely than its Schwarzschild radius. Limitations on measuring mass and velocity mean that the position and momentum of a black hole cannot be simultaneously known more precisely than 2 h rs/lP , a value more restrictive than the Heisenberg uncertainty principle. Hidden information about a black hole’s position and momentum results in many possible microstates that are indistinguishable to an observer. One way to interpret the physical meaning of Bekenstein‐Hawking entropy is as a measure of the number of these microstates. This interpretation allows entropy to be generalized to objects in any gravitational field, because gravitational redshift increases uncertainty about position and momentum for objects in all gravitational fields, not just those of black holes.

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来源期刊

Physics Essays PHYSICS, MULTIDISCIPLINARY-

自引率

83.30%

发文量

审稿时长

6-12 weeks

期刊介绍： Physics Essays has been established as an international journal dedicated to theoretical and experimental aspects of fundamental problems in Physics and, generally, to the advancement of basic knowledge of Physics. The Journal’s mandate is to publish rigorous and methodological examinations of past, current, and advanced concepts, methods and results in physics research. Physics Essays dedicates itself to the publication of stimulating exploratory, and original papers in a variety of physics disciplines, such as spectroscopy, quantum mechanics, particle physics, electromagnetic theory, astrophysics, space physics, mathematical methods in physics, plasma physics, philosophical aspects of physics, chemical physics, and relativity.