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An isotropic analytical model for charged stars

Facultad de Ciencias Físico Matemáticas, Universidad Michoacana de San Nicolás de Hidalgo, Edificio B Ciudad Universitaria, Morelia Michoacán, México

E-mail Address: joaquin@fismat.umich.mx

Corresponding author.

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Gabino Estevez-Delgado

Facultad de Químico Farmacobiología, Universidad Michoacana de San Nicolás de Hidalgo, Tzintzuntzan No. 173, Colonia Matamoros, C.P. 58240 Morelia Michoacán, México

E-mail Address: gabino.estevez@umich.mx

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Noel Enrique Rodríguez Maya

Departamento de Sistemas y Computación, Instituto Tecnológico de Zitácuaro, Av. Tecnológico No. 186, Colonia Manzanillos, C.P. 61534 Heroica Zitácuaro, Michoacán, México

E-mail Address: noel.rm@zitacuaro.tecnm.mx

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José Martínez Peña

Escuela Preparatoria “Ing. Pascual Ortiz Rubio”, Universidad Michoacana de San Nicolás, de Hidalgo, Plan de Ayala No. 156, C.P. 58000 Morelia Michoacán, México

E-mail Address: jose.martinez.pena@umich.mx

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, and

Modesto Pineda Duran

Instituto Tecnológico Superior de Tacámbaro, Av. Tecnológico No. 201, Zona el Gigante, C.P. 61650 Tacambaro Michoacán, México

E-mail Address: mpinedad@hotmail.com

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https://doi.org/10.1142/S0217732321500899Cited by:5 (Source: Crossref)

Abstract

In this investigation report, we present a perfect charged fluid solution for a static and spherically symmetric spacetime; for its construction, we suppose a metric potential, $g_{t t}$ $g_{t t}$ , and a specific form of the electric field’s intensity, $E$ $E$ , in such a manner that the resulting stellar model is physically acceptable and stable. The model presented depends on two parameters $(w, α)$ $(w, α)$ related to the compactness and the magnitude of the electric field and these same parameters will generate different possibilities for the behavior of the speed of sound. For the particular case in which $α = 0$ $α = 0$ , we obtain once more a chargeless model constructed previously, the compactness for the charged model case is greater than in the chargeless case. As an effect of the charge, the model admits two regions for the parameter $α$ $α$ , in one of these the speed of sound is a monotonic decreasing function and in the other it is a monotonic increasing function. By means of a numerical analysis, it is shown that the orders of magnitude associated to the pressure and density are characteristic of the compact stars. In particular for $w = 0.3691670568$ $w = 0.3691670568$ , the range of $α \in [55.57286, 674.5349]$ $α \in [55.57286, 674.5349]$ , which implies that the radius of an object with mass $1 M_{⊙}$ $1 M_{⊙}$ is found between 6554.620 m and 7672.702 m with a maximum central density of $ρ_{b} = 4.354076 \times 1 0^{18} {kg/m}^{3}$ $ρ_{b} = 4.354076 \times 1 0^{18} {kg/m}^{3}$ .

Keywords:

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