1. Decoupled charged anisotropic spherical solutions in Rastall gravity.
- Author
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Sharif, M. and Sallah, M.
- Subjects
- *
GRAVITY , *GEOMETRIC approach , *ELECTROMAGNETIC fields , *REDSHIFT , *PHYSICAL constants , *GRAVITATIONAL potential , *SPACETIME , *EQUATIONS of state - Abstract
This paper uses the gravitational decoupling through the minimal geometric deformation approach and extends a known isotropic solution for a self-gravitating interior to two types of anisotropic spherical solutions in Rastall gravity in the presence of electromagnetic field. By deforming only the radial metric component, the field equations are decoupled into two sets, the first of which corresponds to an isotropic distribution of matter while the second set contains the anisotropic source. We obtain a solution of the first set by employing the charged isotropic Finch-Skea ansatz, whereas a solution for the second set is obtained by adopting two mimic constraints on the pressure and density. The matching conditions at the stellar surface are explored with the exterior geometry given by the deformed Reissner–Nordström spacetime. For the two fixed values of the Rastall and charge parameters, we investigate physical features of both solutions through graphical analysis of the energy conditions, equation of state parameters, surface redshift and compactness function. The stability of both solutions is also studied through the Herrera cracking approach and causality condition. We deduce that while both solutions are physically viable, only the solution corresponding to the pressure-like constraint is stable. • Gravitational decoupling approach is used to find charged exact solutions in Rastall gravity. • We obtain a solution by employing charged isotropic Finch-Skea ansatz. • Investigate physical viability of both solutions through graphical analysis of the physical quantities. • Stability of both solutions is also studied through the Herrera cracking approach and causality condition. • We deduce that both solutions are physically viable but only the first solution is stable. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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