An EGD model in the background of embedding class I space–time

In this work we study class I interior solutions supported by anisotropic polytropes. The generalized Lane–Emden equation compatible with the embedding condition is obtained and solved for a different set of parameters in both the isothermal and non-isothermal regimes. For completeness, the Tolman mass is computed and analysed to some extend. As a complementary study we consider the impact of the Karmarkar condition on the mass and the Tolman mass functions respectively. Comparison with other results in literature are discussed.

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“…Finally, introducing (42) in (35) we arrive to the class I generalized Lane-Emden equation for γ = 1 (isothermal case),…”

Section: The Class I Conditionmentioning

confidence: 99%

Class I polytropes for anisotropic matter

et al. 2021

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“…The gravitational decoupling was also used to study gravity coupled to hidden gauge fields [30] and to derive new physical features of superfluid stars [31]. Other models involving the gravitational decoupling have been developed [32][33][34][35][36][37][38][39][40][41][42][43][44][45][46][47][48][49], with relevant applications to recently observed anisotropic stellar configurations [50][51][52][53][54][55][56][57][58][59][60][61][62][63][64][65][66][67]. Also, the quantum entanglement entropy of anisotropic gravitational decoupled black holes revealed important directions towards placing the gravitational decoupling method in gauge/gravity duality [68,69].…”

Section: Introductionmentioning

confidence: 99%

Gravitational decoupling of generalized Horndeski hybrid stars

Rocha

2022

Eur. Phys. J. C

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Gravitational decoupled compact polytropic hybrid stars are here addressed in generalized Horndeski scalar-tensor gravity. Additional physical properties of hybrid stars are scrutinized and discussed in the gravitational decoupling setup. The asymptotic value of the mass function, the compactness, and the effective radius of gravitational decoupled hybrid stars are studied for both cases of a bosonic and a fermionic prevalent core. These quantities are presented and discussed as functions of Horndeski parameters, the decoupling parameter, the adiabatic index, and the polytropic constant. Important corrections to general relativity and generalized Horndeski scalar-tensor gravity, induced by the gravitational decoupling, comply with available observational data. Particular cases involving white dwarfs, boson stellar configurations, neutron stars, and Einstein–Klein–Gordon solutions, formulated in the gravitational decoupling context, are also scrutinized.

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“…The general framework for studying class I spacetimes within the context of the MGD and CGD approaches were provided by Maurya and his collaborators. [ 48–50 ] The MGD in axially symmetric systems and rotating black holes has been applied by Contreras et al. [ 43 ] as well as some other works on dark matter, black holes and Dirac stars in the context of MGD are obtained by the authors.…”

Section: Introductionmentioning

confidence: 99%

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

Maurya

Tello‐Ortiz

Govender

2021

Fortschritte der Physik

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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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An EGD model in the background of embedding class I space–time

Cited by 46 publications

References 123 publications

Class I polytropes for anisotropic matter

Class I polytropes for anisotropic matter

Gravitational decoupling of generalized Horndeski hybrid stars

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

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