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Exploring Physical Properties of Gravitationally Decoupled Anisotropic Solution in 5<i>D</i> Einstein‐Gauss‐Bonnet Gravity

S. K. MauryaDepartment of Mathematical and Physical Sciences College of Arts and Sciences University of Nizwa Nizwa Sultanate of OmanFrancisco Tello‐OrtizDepartamento de Física Facultad de Ciencias Básicas Universidad de Antofagasta Casilla 170 Antofagasta ChileMegandhren GovenderDepartment of Mathematics Durban University of Technology Durban 4000 South Africa
2021en
ABI

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Abstract In this paper we present two new classes of solutions describing compact objects within the framework of five‐dimensional Einstein‐Gauss‐Bonnet (EGB) gravity. We employ the Complete Geometric Deformation (CGD) formalism which extends the Minimal Geometric Deformation (MGD) technique adopted in earlier investigations to generate anisotropic models from known isotropic solutions. The two solutions presented arise from mimicking the constraint for the pressure and density respectively which generate independent deformation functions. Rigorous physical tests show that contributions from CDG suppress the effective pressure but enhances the effective density and mass of the compact object, with the suppression/enhancement being modified by the EGB coupling constant. One of the highlights in our findings is that the deformation function along the radial component in CDG is nonzero at the boundary when we mimic both the pressure and density while in MGD we observe a vanishing of this deformation function at the boundary of the fluid configuration only for the pressure constraint. The difference in behavior of the deformation function at the surface predicts different stellar characteristics such as mass‐to‐radius and surface redshifts.

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