Energy-Momentum Complex in Higher Order Curvature-Based Local Gravity

Inhaled particles Pub Date : 2022-08-04 DOI:10.3390/particles5030026

S. Capozziello, M. Capriolo, G. Lambiase

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引用次数: 1

Abstract

An unambiguous definition of gravitational energy remains one of the unresolved issues of physics today. This problem is related to the non-localization of gravitational energy density. In General Relativity, there have been many proposals for defining the gravitational energy density, notably those proposed by Einstein, Tolman, Landau and Lifshitz, Papapetrou, Møller, and Weinberg. In this review, we firstly explored the energy–momentum complex in an nth order gravitational Lagrangian L=Lgμν,gμν,i1,gμν,i1i2,gμν,i1i2i3,⋯,gμν,i1i2i3⋯in and then in a gravitational Lagrangian as Lg=(R¯+a0R2+∑k=1pakR□kR)−g. Its gravitational part was obtained by invariance of gravitational action under infinitesimal rigid translations using Noether’s theorem. We also showed that this tensor, in general, is not a covariant object but only an affine object, that is, a pseudo-tensor. Therefore, the pseudo-tensor ταη becomes the one introduced by Einstein if we limit ourselves to General Relativity and its extended corrections have been explicitly indicated. The same method was used to derive the energy–momentum complex in fR gravity both in Palatini and metric approaches. Moreover, in the weak field approximation the pseudo-tensor ταη to lowest order in the metric perturbation h was calculated. As a practical application, the power per unit solid angle Ω emitted by a localized source carried by a gravitational wave in a direction x^ for a fixed wave number k under a suitable gauge was obtained, through the average value of the pseudo-tensor over a suitable spacetime domain and the local conservation of the pseudo-tensor. As a cosmological application, in a flat Friedmann–Lemaître–Robertson–Walker spacetime, the gravitational and matter energy density in f(R) gravity both in Palatini and metric formalism was proposed. The gravitational energy–momentum pseudo-tensor could be a useful tool to investigate further modes of gravitational radiation beyond two standard modes required by General Relativity and to deal with non-local theories of gravity involving □−k terms.

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基于高阶曲率的局部重力中的能量-动量复合体

引力能的明确定义仍然是当今物理学中未解决的问题之一。这个问题与引力能量密度的非局域化有关。在广义相对论中，有许多关于定义引力能密度的建议，特别是爱因斯坦、托尔曼、朗道和Lifshitz、Papapetrou、m . ller和Weinberg提出的。在本文中，我们首先探索了n阶引力拉格朗日L=Lgμν，gμν，i1,gμν，i1i2,gμν，i1i2i3，⋯⋯，gμν，i1i2i3⋯⋯中的能量-动量复形，然后在引力拉格朗日中探索了Lg=(R¯+a0R2+∑k=1pakR□kR)−g。它的引力部分是由无限小刚性平移下引力作用的不变性利用诺特定理得到的。我们也证明了这个张量，一般来说，不是一个协变对象而是一个仿射对象，也就是说，一个伪张量。因此，如果我们把自己限制在广义相对论中，并且它的扩展修正已经明确地指出，那么伪张量ταη就变成了爱因斯坦引入的张量。用帕拉蒂尼法和度量法推导了fR重力中的能量动量复合体。在弱场近似下，计算了度规扰动h的最低阶伪张量ταη。作为实际应用，通过伪张量在合适的时空域中的平均值和伪张量的局部守恒，得到了引力波在x^方向上，在合适的规范下，在固定波数k下，引力波携带的局域源所发射的单位立体角功率Ω。作为一个宇宙学应用，在平坦的friedman - lema - robertson - walker时空中，提出了在Palatini和度量形式下f(R)重力中的引力和物质能量密度。引力能量-动量伪张量可以成为一个有用的工具，用于研究广义相对论所要求的两个标准模式之外的引力辐射的进一步模式，以及处理涉及□−k项的非局部引力理论。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Inhaled particles

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