New structures in gravitational radiation

IF 1 4区 物理与天体物理 Q3 PHYSICS, MATHEMATICAL
L. Bieri
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引用次数: 3

Abstract

We investigate the Einstein vacuum equations as well as the Einstein-null fluid equations describing neutrino radiation. We find new structures in gravitational waves and memory for asymptotically-flat spacetimes of slow decay. It has been known that for stronger decay of the data, including data being stationary outside a compact set, gravitational wave memory is finite and of electric parity only. In this article, we investigate general spacetimes that are asymptotically flat in a rough sense. That is, the decay of the data to Minkowski space towards infinity is very slow. As a main new feature, we prove that there exists diverging magnetic memory sourced by the magnetic part of the curvature tensor (a) in the Einstein vacuum and (b) in the Einstein-null-fluid equations. The magnetic memory occurs naturally in the Einstein vacuum setting (a) of pure gravity. In case (b), in the ultimate class of solutions, the magnetic memory contains also a curl term from the energy-momentum tensor for neutrinos also diverging at the aforementioned rate. The electric memory diverges too, it is generated by the electric part of the curvature tensor and in the Einstein-null-fluid situation also by the corresponding energy-momentum component. In addition, we find a panorama of finer structures in these manifolds. Some of these manifest themselves as additional contributions to both electric and magnetic memory. Our theorems hold for any type of matter or energy coupled to the Einstein equations as long as the data decays slowly towards infinity and other conditions are satisfied. The new results have a multitude of applications ranging from mathematical general relativity to gravitational wave astrophysics, detecting dark matter and other topics in physics.
引力辐射的新结构
我们研究了描述中微子辐射的爱因斯坦真空方程和爱因斯坦零流体方程。我们在缓慢衰减的渐近平坦时空的引力波和记忆中发现了新的结构。众所周知,对于数据的更强衰减,包括在紧集之外的静止数据,引力波记忆是有限的,并且只有电宇称。在这篇文章中,我们研究了在粗略意义上渐近平坦的一般时空。也就是说,数据向闵可夫斯基空间的无穷衰减是非常缓慢的。作为一个主要的新特征,我们证明了在爱因斯坦真空中(a)和在爱因斯坦-零流体方程中(b)曲率张量的磁性部分存在发散磁记忆。磁记忆在纯重力的爱因斯坦真空环境(a)中自然发生。在情形(b)中,在终极解类中,磁记忆也包含一个旋度项,它来自中微子的能量动量张量,也以上述速率发散。电记忆也是发散的,它是由曲率张量的电部分产生的,在爱因斯坦-零流体情况下,它也是由相应的能量-动量分量产生的。此外,我们还在这些流形中发现了更精细的结构全景。其中一些表现为对电记忆和磁记忆的额外贡献。我们的定理适用于与爱因斯坦方程耦合的任何类型的物质或能量,只要数据缓慢地向无限衰减并且满足其他条件。新的结果有大量的应用,从数学广义相对论到引力波天体物理学,探测暗物质和其他物理学主题。
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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来源期刊
Advances in Theoretical and Mathematical Physics
Advances in Theoretical and Mathematical Physics 物理-物理:粒子与场物理
CiteScore
2.20
自引率
6.70%
发文量
0
审稿时长
>12 weeks
期刊介绍: Advances in Theoretical and Mathematical Physics is a bimonthly publication of the International Press, publishing papers on all areas in which theoretical physics and mathematics interact with each other.
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