A spherically symmetric model of anisotropic fluid for strange quark spheres

Abdelghani Errehymy; Mohammed Daoud; El Hassan Sayouty

doi:10.1140/epjc/s10052-019-6862-9

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2024 Impact factor 4.8

Particles and Fields

Open Access

Eur. Phys. J. C (2019) 79: 346
https://doi.org/10.1140/epjc/s10052-019-6862-9

Regular Article - Theoretical Physics

A spherically symmetric model of anisotropic fluid for strange quark spheres

Abdelghani Errehymy¹^*, Mohammed Daoud²^,3 and El Hassan Sayouty¹

¹ Laboratory of High Energy Physics and Condensed Matter (LPHEMaC), Department of Physics, Faculty of Sciences Aïn Chock, University of Hassan II, B.P. 5366, Mâarif, Casablanca, 20100, Morocco
² Department of Physics, Faculty of Sciences, University of Ibn Tofail, B.P. 133, Kenitra, 14000, Morocco
³ Abdus Salam International Centre for Theoretical Physics, Miramare, Trieste, Italy

^* e-mail: abdelghani.errehymy@gmail.com

Received: 23 December 2018
Accepted: 7 April 2019
Published online: 17 April 2019

Abstract

In the present work, we try to find a solution without singularity of Einstein’s field equations for the spherically symmetric perfect fluid objects, accurately strange quark spheres, taking into consideration Schwarzschild metric as the outside space-time. An ensemble of inside solutions found on the basis of the simplest linear state equation in the specific form $p_r =\alpha \rho -\beta$ . The energy density $\rho (r)$ , the radial pressure $$p_r (r)$$ and the tangential pressure $$p_t (r)$$ are devoid of any singularity and exhibit a well-behaved nature within the generalized anisotropic solution for compact spherical object. The generalized TOV equation is very much preserved inside the system and all energy conditions are excellent. The stability of the matter distribution of our system is checked by the concept of Herrera’s cracking and the condition of causality is all around fulfilled for our models. The adiabatic index of our specific configuration is greater than 4 / 3 in all interior points of the system and the mass-to-radius ratio in our situation is determined also lies within the Buchdahl limit i.e. $\hbox {M}/\hbox {R}\le 4/3\,\left( {\approx 0.444} \right)$ . We explore the physical characteristics based on the analytical model developed for relativistic compact stellar spheres inside the framework of the general theory of relativity. The evaluated mass and radius are in close concurrence with the observational information. We show that various physical characteristics of the known strange spherical object, viz. PSR J1614-2230, Vela X-1, 4U 1608-52, PSR J1903+327, 4U 1820-30, Cen X-3, Her X-1, and SAX J1808.4-3658, can be described by the current model.