f(Q,T)引力下存在暗物质密度剖面的相对论虫洞动力学

IF 5 2区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS

Physics of the Dark Universe Pub Date : 2024-09-03 DOI:10.1016/j.dark.2024.101636

Jitendra Kumar , S.K. Maurya , Sweeti Kiroriwal , Abdelghani Errehymy , Kairat Myrzakulov , Zhanbala Umbetova

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引用次数: 0

摘要

本文研究了一种特殊引力理论中虫洞模型的特征，即f(Q,T)=σQ+λT。在这里，我们使用暗物质剖面推导虫洞模型，暗物质剖面分别是艾纳斯托尖峰和伪等温线，即ρES=ρ0exp-2ζrrsζ-1和ρPI=ω1+μr2。得到的虫洞形状函数解满足必要的度量要求。本研究的重点是参数σ和λ如何影响虫洞解的平衡态和违反能量条件。我们发现每个模型都偏离了空能量阈值，这表明虫洞稳定所需的奇异物质的存在。此外，我们还利用嵌入图破译了虫洞模型的几何结构。此外，我们还研究了引力的排斥效应。当研究虫洞周围的大地运动时，我们发现光子偏转角为负值，这表明两种模型都存在引力的排斥效应。

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Dynamics of relativistic wormholes in the presence of dark matter density profile within f(Q,T) gravity

In this paper, we study the characteristics of wormhole models in a particular gravity theory, namely $f (Q, T) = σ Q + λ T$ . Here, we derived the wormhole models by using dark matter profiles that are Einasto spike and Pseudo isothermal that is $ρ_{E S} = ρ_{0} exp (\frac{- 2}{ζ} ({(\frac{r}{r_{s}})}^{ζ} - 1))$ and $ρ_{P I} = \frac{ω}{1 + μ r^{2}}$ respectively. The obtained solutions for the wormhole’s shape function satisfy the necessary metric requirements. This study focuses on how the parameters $σ$ and $λ$ affect the equilibrium state of the wormhole solution and violations of energy conditions. We found that every model deviates from the null energy threshold, suggesting the existence of exotic matter that is required for the wormholes to be stable. Furthermore, we deciphered the geometry of wormhole models using embedding diagrams. Additionally, we investigated the repulsive effect of gravity. When the geodesic motion around the wormholes is examined, it is discovered that the photon deflection angle is negative, suggesting the existence of gravity’s repulsive effect for both models.

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来源期刊

Physics of the Dark Universe ASTRONOMY & ASTROPHYSICS-

CiteScore

9.60

自引率

7.30%

发文量

118

审稿时长

61 days

期刊介绍： Physics of the Dark Universe is an innovative online-only journal that offers rapid publication of peer-reviewed, original research articles considered of high scientific impact. The journal is focused on the understanding of Dark Matter, Dark Energy, Early Universe, gravitational waves and neutrinos, covering all theoretical, experimental and phenomenological aspects.