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Autori principali: Gao, Yuan-Kun, Huang, Da, Ma, Yong-Liang, Tang, Yong, Wu, Yue-Liang, Zhou, Yu-Feng
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2403.17619
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author Gao, Yuan-Kun
Huang, Da
Ma, Yong-Liang
Tang, Yong
Wu, Yue-Liang
Zhou, Yu-Feng
author_facet Gao, Yuan-Kun
Huang, Da
Ma, Yong-Liang
Tang, Yong
Wu, Yue-Liang
Zhou, Yu-Feng
contents We explore the new physics phenomena of gravidynamics governed by the inhomogeneous spin gauge symmetry based on the gravitational quantum field theory. Such a gravidynamics enables us to derive the generalized Einstein equation and an equation beyond it. To simplify the analyses, we linearize the dynamic equations of gravitational interaction by keeping terms up to the leading order in the dual gravigauge field. We then apply the linearized dynamic equations into two particular gravitational phenomena. First, we consider the linearized equations in the absence of source fields, which is shown to have five physical propagating polarizations as gravitational waves, i.e., two tensor modes, two vector modes, and one scalar, instead of two tensor polarizations in the general relativity. Second, we examine the Newtonian limit in which the gravitational fields and the matter source distribution are weak and static. By deriving the associated Poisson equation, we obtain the exact relation of the fundamental interaction coupling in the gravidynamics with the experimentally measured Newtonian constant. We also make use of nonrelativistic objects and relativistic photons to probe the Newtonian field configurations. In particular, the experiments from the gravitational deflection of light rays and the Shapiro time delay can place stringent constraints on the linearized gravidynamics in the gravitational quantum field theory.
format Preprint
id arxiv_https___arxiv_org_abs_2403_17619
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Linear dynamics and classical tests of the gravitational quantum field theory
Gao, Yuan-Kun
Huang, Da
Ma, Yong-Liang
Tang, Yong
Wu, Yue-Liang
Zhou, Yu-Feng
General Relativity and Quantum Cosmology
High Energy Physics - Phenomenology
High Energy Physics - Theory
We explore the new physics phenomena of gravidynamics governed by the inhomogeneous spin gauge symmetry based on the gravitational quantum field theory. Such a gravidynamics enables us to derive the generalized Einstein equation and an equation beyond it. To simplify the analyses, we linearize the dynamic equations of gravitational interaction by keeping terms up to the leading order in the dual gravigauge field. We then apply the linearized dynamic equations into two particular gravitational phenomena. First, we consider the linearized equations in the absence of source fields, which is shown to have five physical propagating polarizations as gravitational waves, i.e., two tensor modes, two vector modes, and one scalar, instead of two tensor polarizations in the general relativity. Second, we examine the Newtonian limit in which the gravitational fields and the matter source distribution are weak and static. By deriving the associated Poisson equation, we obtain the exact relation of the fundamental interaction coupling in the gravidynamics with the experimentally measured Newtonian constant. We also make use of nonrelativistic objects and relativistic photons to probe the Newtonian field configurations. In particular, the experiments from the gravitational deflection of light rays and the Shapiro time delay can place stringent constraints on the linearized gravidynamics in the gravitational quantum field theory.
title Linear dynamics and classical tests of the gravitational quantum field theory
topic General Relativity and Quantum Cosmology
High Energy Physics - Phenomenology
High Energy Physics - Theory
url https://arxiv.org/abs/2403.17619