Charged spherical solution in torsion and matter coupling gravity and influence of torsion parameter and electric charge on compact stars in lower mass gap

IF 4.3 3区材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-03-27 DOI:10.1093/ptep/ptae043

S K Maurya, Abdelghani Errehymy, G Mustafa, Orhan Donmez, Kottakkaran Sooppy Nisar, Abdel-Haleem Abdel-Aty

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Abstract

In this study, we explore a new exact solution for a charged spherical model as well as the astrophysical implications of the torsion parameter χ1 and electric charge Q on compact stars in lower mass gaps in the $f(\mathcal {T})$ gravity framework. Commencing with the field equations that describe anisotropic matter distributions, we select a well-behaved ansatz for the radial component of the metric function, along with an appropriate formulation for the electric field. The resulting model undergoes rigorous testing to ensure its qualification as a physically viable compact object within the $f(\mathcal {T})$ gravity background. We extensively investigate two factors: χ1 and Q, carefully analyzing their impacts on the mass, radius, and stability of the star. Our analyses demonstrate that our models exhibit well-behaved behavior, free from singularities, and can successfully explain the existence of a wide range of observed compact objects. These objects have masses ranging from $0.85^{+0.15}_{-0.15}$ to 2.67 M⊙, with the upper value falling within the mass gap regime observed in gravitational events like GW190814. A notable finding of this study has two aspects: we observe significant effects on the maximum mass (Mmax) and the corresponding radii of these objects. Increasing values of χ1 lead to higher Mmax (approximately $2.64^{+0.13}_{-0.14}$) and smaller radii (approximately $10.40^{+0.16}_{-0.60}$), suggesting the possibility of the existence of massive neutron stars (NSs) within the system. Conversely, increasing values of Q result in a decrease in Mmax (approximately $1.70^{+0.05}_{-0.03}$) and larger radii (approximately $13.71^{+0.19}_{-0.20}$). Furthermore, an intriguing observation arises from comparing the results: for all values of χ1, non-rotating stars possess higher masses compared to slow-rotating stars, while this trend is reversed when adjusting Q.

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扭转和物质耦合引力中的带电球面解以及扭转参数和电荷对低质量间隙紧凑恒星的影响

在本研究中，我们探讨了带电球面模型的新精确解，以及在$f(\mathcal {T})$引力框架下，扭转参数χ1和电荷Q对低质量间隙紧凑恒星的天体物理学影响。从描述各向异性物质分布的场方程开始，我们为度量函数的径向分量选择了一个良好的解析，并为电场选择了一个适当的公式。由此产生的模型要经过严格的测试，以确保它在 $f(\mathcal {T})$ 引力背景下是一个物理上可行的紧凑物体。我们广泛研究了两个因素：χ1和Q，仔细分析它们对恒星质量、半径和稳定性的影响。我们的分析表明，我们的模型表现出良好的行为，没有奇点，可以成功地解释大量观测到的紧凑天体的存在。这些天体的质量从$0.85^{+0.15}_{-0.15}$到2.67 M⊙不等，其中上限值属于在GW190814等引力事件中观测到的质量差距范围。这项研究的一个显著发现有两个方面：我们观察到这些天体的最大质量（Mmax）和相应半径受到了显著影响。χ1值的增加会导致更大的最大质量（Mmax）（约为2.64^{+0.13}_{-0.14}$）和更小的半径（约为10.40^{+0.16}_{-0.60}$），这表明系统中可能存在大质量中子星（NSs）。相反，Q 值的增大会导致 Mmax 值的减小（约为 1.70^{+0.05}_{-0.03}$）和半径的增大（约为 13.71^{+0.19}_{-0.20}$）。此外，比较这些结果还发现了一个有趣的现象：在所有的χ1值下，非旋转恒星的质量都比慢旋转恒星的质量大，而在调整Q值时，这一趋势却发生了逆转。

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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