Complexity‐Free Anisotropic Solution of Buchdahl's Model and Energy Exchange Between Relativistic Fluids by Extended Gravitational Decoupling

Maurya, S. K.; Singh, Ksh. Newton; Govender, M.; Ray, Saibal

doi:10.1002/prop.202300023

Cited by 13 publications

(2 citation statements)

References 136 publications

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“…Maurya et al [65] adopted this metric and discussed eight different cases for Buchdahl's dimensionless parameter and found all of them valid at every point within the interior geometry. Various authors used this metric to produce viable as well stable charged/ uncharged interiors in the contexts of  and   f , ( ) theory [66][67][68]. This metric is adopted as follows…”

Section: Buchdahl Solution and Boundary Conditionsmentioning

confidence: 99%

Decoupled anisotropic Buchdahl’s relativistic models in f( R,T ) theory

Naseer,

Sharif

2024

Phys. Scr.

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This paper constructs three different anisotropic extensions of theexisting isotropic solution to the modified field equations throughthe gravitational decoupling in $f(\mathbb{R},\mathbb{T})$ theory.For this, we take a static sphere that is initially filled with theisotropic fluid and then add a new gravitational source producinganisotropy in the system. The field equations now correspond to thetotal matter configuration. We transform the radial metric componentto split these equations into two sets characterizing their parentsources. The unknowns comprising in the first set are determined byconsidering the Buchdahl isotropic solution. On the other hand, weemploy different constraints related to the additional gravitationalsource and make the second system solvable. Further, the constanttriplet in Buchdahl solution is calculated by means of matchingcriteria between the interior and exterior geometries at thespherical boundary. The mass and radius of a compact star LMC X-4are used to analyze the physical relevancy of the developed models.We conclude that our resulting models II and III are inwell-agreement with acceptability conditions for the consideredvalues of the parameters.

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Section: Buchdahl Solution and Boundary Conditionsmentioning

confidence: 99%

Decoupled anisotropic Buchdahl’s relativistic models in f( R,T ) theory

Naseer,

Sharif

2024

Phys. Scr.

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“…Considering the influence of the parameter σ, it is observed that increasing its value significantly increases both the pressure components P P , r { } ^, while ò and Δ eff undergo a mild increase as σ rises as described in figures 6-8. The exchange of energy between the relativistic fluid configurations T αβ and Θ αβ in the context of EGD-scheme has been a topic of great interest [51,52,70]. Understanding the dynamics of energy transfer among various fluid components enables us to scrutinize phenomena such as gravitational waves and the evolution of these relativistic systems.…”

Section: Summary and Discussionmentioning

confidence: 99%

Complexity-free charged anisotropic Finch-Skea model satisfying Karmarkar condition

Khan,

Yousaf

2024

Phys. Scr.

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By making use of the extended geometric deformation (EGD) approach, this work explores the charged anisotropic Finch-Skea solution satisfying the Karmarkar condition. The implementation of EGD-approach splits the original gravitational source into perfect and anisotropic ﬂuid conﬁgurations. We employ Herrera’s complexity factor [1] formalism to develop theoretical models characterizing the role of complexity on the Finch-Skea solution. The use of the Karmarkar condition enables us to derive a solution for the isotropic, charged spherical conﬁguration by deﬁning a Finch-Skea metric that evaluates the deformation functions. The Finch-Skea ansatz serves as a valuable seed model for solving the seed-gravitational source, however, the zero-complexity constraint is employed to solve the remaining set of anisotropic equations. We match the interior metric manifold attributed to the spherically symmetric ansatz with the classical Reissner-Nordström metric. We examined the inﬂuence of gravitational decoupling on the anisotropic Finch-Skea solution. We also analyzed the physical viability of the presented results using graphical representations for the thermodynamic variables.

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A perturbative approach to complexity during dissipative collapse

Govender,

Bogadi,

Govender

et al. 2024

Astrophys Space Sci

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Radiative gravitational collapse is an important and much studied phenomenon in astrophysics. Einstein’s theory of general relativity (GR) is well suited to describing such processes provided closure of the system of nonlinear differential equations is achieved. Within a perturbative scheme, the property of vanishing complexity factor is used in order to complete the description of the radiative, self-gravitating system. We show that a physically viable model may be obtained which reflects the absence of energy inhomogeneities for lower density systems, in contrast to what might be expected for more aggressive collapse processes.

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Complexity‐Free Anisotropic Solution of Buchdahl's Model and Energy Exchange Between Relativistic Fluids by Extended Gravitational Decoupling

Cited by 13 publications

References 136 publications

Decoupled anisotropic Buchdahl’s relativistic models in f( R,T ) theory

Decoupled anisotropic Buchdahl’s relativistic models in f( R,T ) theory

Complexity-free charged anisotropic Finch-Skea model satisfying Karmarkar condition

A perturbative approach to complexity during dissipative collapse

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