史瓦西度规的物理优先方法

K. Kassner
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引用次数: 8

摘要

众所周知,史瓦西度规不能仅基于前广义相对论物理学推导出来,这意味着只能使用狭义相对论、爱因斯坦等效原理和牛顿极限。推导它的标准方法是使用爱因斯坦的场方程。然而,与牛顿引力和电动力学的类比表明,可能存在一种更有建设性的方法来研究点质量的引力场。事实证明,两个貌似合理的假设包含了所需的额外物理条件。这些可以在不调用场方程的情况下推导出精确的史瓦西度规。由于它们表达的要求本质上是为球对称情况设计的,因此它们不如爱因斯坦用来构造场方程的假设那么普遍和有力。结果表明,这些隐含了这里给出的假设,但相反的假设并不完全正确。该方法提供了一种相当快速的方法来计算任意坐标下具有平稳性的史瓦西度规,并对引力场中波的行为有了新的认识。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Physics-First Approach to the Schwarzschild Metric
As is well-known, the Schwarzschild metric cannot be derived based on pre-general-relativistic physics alone, which means using only special relativity, the Einstein equivalence principle and the Newtonian limit. The standard way to derive it is to employ Einstein's field equations. Yet, analogy with Newtonian gravity and electrodynamics suggests that a more constructive way towards the gravitational field of a point mass might exist. As it turns out, the additional physics needed is captured in two plausible postulates. These permit to deduce the exact Schwarzschild metric without invoking the field equations. Since they express requirements essentially designed for use with the spherically symmetric case, they are less general and powerful than the postulates from which Einstein constructed the field equations. It is shown that these imply the postulates given here but that the converse is not quite true. The approach provides a fairly fast method to calculate the Schwarzschild metric in arbitrary coordinates exhibiting stationarity and sheds new light on the behavior of waves in gravitational fields.
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