Particle and light motion in Lyra-Schwarzschild spacetime

R. R. Cuzinatto, E. de Morais, Bruto Max Pimentel
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Abstract

In this paper we recall the static and spherically symmetric solution derived within LyST gravity. LyST stands for “Lyra Scalar-Tensor” and is a scalar-tensor proposal for the gravitational interaction modifying general relativity by adopting Lyra manifold as the spacetime substrate. Lyra manifold is characterized both by the metric tensor gµν(x) and the scale φ(x); the latter being an integral part of the definition of reference frame. In a previous work, we have launched the formal geometrical basis of LyST, we have proposed an associated action integral for the gravitational interaction, we have derived the field equations generalizing Einstein field equation, and we have solved these equation to obtain the generalized version of Schwarzschild line element in Lyra manifold. This lead us to Lyra-Schwarzschild spacetime, which is further explored in the present paper. Herein, the trajectories of test particles is thoroughly studied. This is done for both massive particles and massless particles. The geodesic equations are built and solved. The effective potential associated to the motion of these particles around the source is determined and characterized. The possible trajectories include gravitational capture, scattering, bounded orbits, stable and unstable circular orbits, near-horizon motion. The innermost circular orbit allowed for massive particles is determined and compared to the one predicted by GR. The last photon orbit is also calculated for Lyra-Schwarzschild metric. The equation for the periastron shift in the context of Lyra-Schwarzschild solution is constructed; its application to observational data could be useful to constrain the parameters typical of LyST, telling it apart from GR.
天琴-施瓦兹柴尔德时空中的粒子和光运动
本文回顾了在 LyST 引力中得出的静态球对称解。LyST 是 "Lyra Scalar-Tensor"(天琴座标量张量)的缩写,是通过采用天琴座流形作为时空基底来修正广义相对论的引力相互作用标量张量方案。天琴座流形由度量张量 gµν(x) 和尺度 φ(x) 两部分组成,后者是参照系定义的一个组成部分。在之前的工作中,我们提出了天琴座流形的形式几何基础,提出了引力相互作用的相关作用积分,导出了广义爱因斯坦场方程,并通过求解这些方程得到了天琴座流形中广义版的施瓦兹柴尔德线元。本文将进一步探讨天琴座-施瓦兹柴尔德时空。本文对测试粒子的轨迹进行了深入研究。这既针对大质量粒子,也针对无质量粒子。本文建立并求解了大地方程。确定并描述了与这些粒子绕源运动相关的有效势能。可能的运动轨迹包括引力俘获、散射、有界轨道、稳定和不稳定的圆形轨道、近地平线运动。确定了大质量粒子允许的最内层圆形轨道,并与 GR 预测的轨道进行了比较。最后一个光子轨道也是根据 Lyra-Schwarzschild 公设计算的。构建了天琴座-斯瓦兹柴尔德解背景下的近天球移动方程;将其应用于观测数据可能有助于约束天琴座-斯瓦兹柴尔德解的典型参数,从而将其与全球定位系统区分开来。
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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