Charged compact star in f(R, T) gravity in Tolman–Kuchowicz spacetime

Rej, Pramit; Bhar, Piyali; Govender, M.

doi:10.1140/epjc/s10052-021-09127-3

Cited by 64 publications

(41 citation statements)

References 61 publications

(57 reference statements)

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“…In the end, we came to the conclusion that we have derived new, non-singular and horizonless gravastar model for braneworld gravity with the impact of Kuchowicz metric potential. Generally, with special metric potential it is more challenging to obtain physically acceptable solutions, but, as one could notice, interest to the Tolman-Kuchowicz metric potentials for the compact objects (exotic stars for example) have grown in this decade (see [37][38][39][40][41][42]), and thus it is important to test the Kuchowicz spacetime on static gravastars.…”

Section: Discussionmentioning

confidence: 99%

Kuchowicz gravastars in the braneworld formalism

Sokoliuk,

Baransky,

Sahoo

2022

Preprint

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In the current article, we study isotropic static spherically symmetric gravastars without charge under the framework of braneworld gravity (dimensionally reduced RS-II braneworld with positive brane tension) using the metric potential of Kuchowicz type (which is physically acceptable, nonsingular and stable) in the Mazur-Motolla conjucture. We derived the Kuchowicz free parameters from the junction conditions assuming Schwarzschild vacuum without cosmological constant. As well, we assume that the interior is filled with Dark Energy (DE-like) fluid, shell with ultrarelativistic stiff fluid. Adopting this conditions, we probed several physical aspects of the gravastars, such as proper length, shell energy and entropy, surface redshift and adiabatic index, interior region mass.

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Section: Discussionmentioning

confidence: 99%

Kuchowicz gravastars in the braneworld formalism

Sokoliuk,

Baransky,

Sahoo

2022

Preprint

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“…On the other hand, in the context of modified gravity, we now discuss the uses of TK metric potentials. Bhar et al [47] had previously employed this metric potential to model compact objects in Einstein Gauss Bonnet gravity and Javed et al [48] used this metric potential to model anisotropic spheres in f (R, G) modified gravity, Majid and Sharif [49] obtained quark stars in massive Brans-Dicke gravity, Biswas et al [50] obtained an anisotropic strange star with f (R, T ) gravity, Farasat Shamir and Fayyaz [51] obtained the model of charged compact star in f (R) gravity, Naz and Shamir [52] found the stellar model in f (G) gravity, Rej et al [53] studied the charged compact star in the context of f (R, T ) gravity. One notices that TK metric potential succeed in producing the model of a compact star that lacks singularity and meets all the physically acceptable requirements.…”

Section: Interior Spacetime and Field Equationsmentioning

confidence: 99%

Dark Energy Stars in Tolman-Kuchowicz spacetime in the context of Einstein Gravity

Bhar

2022

Preprint

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Dark energy is the component in the present Universe with the greatest abundance, and it is responsible for the accelerating expansion of the Universe. As a result, dark energy is likely to interact with any compact astrophysical object [Muhammad F.A.R. Sakti and Anto Sulaksono, Phys. Rev. D 103, 084042 (2021)]. In present paper, we propose a model for a dark energy star made up of dark and ordinary matter in which the density of dark energy is proportional to the density of isotropic perfect fluid matter. In the context of general relativity, the model is derived in the curved Tolman-Kuchowicz spacetime geometry [Tolman, Phys Rev 55:364, (1939); Kuchowicz, Acta Phys Pol 33:541, (1968)]. Here, we look at how dark energy affects stellar mass, compactness, and equilibrium etc. The physical parameters of the model e.g., pressure, density, mass function, surface redshift etc. are investigated, and the stability of stellar configuration is studied in detail. The model has interesting properties because it meets all energy criteria and is free from central singularities. The maximum allowable mass has been obtained from our model with the help of M − R diagram. We analyse many physical properties of the model and checked that it meets all regularity constraints, is stable, and therefore physically realistic.

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“…However, we will now consider the application of this metric potential in the context of modified gravity. Earlier, Bhar et al [109] used this metric potential to model compact objects in Einstein-Gauss-Bonnet gravity, Javed et al [110] used it to model anisotropic spheres in f (R, G) modified gravity, Biswas et al [111] obtained an anisotropic strange star with f (R, T ) gravity, Majid and Sharif [112] obtained quark stars in massive Brans-Dicke gravity, Naz and Shamir [113] discovered the stellar model in f (G) gravity, Farasat Shamir and Fayyaz [114] discovered the model of charged compact star in f (R) gravity, Rej et al [115] investigated the charged compact star in f (R, T ) gravity, Bhar et al [116] studied anisotropic compact star in Rastall gravity. It's worth noting that this metric potential successfully produces a compact stellar model that is singularity-free and meets all of the physical requirements.…”

Section: Tk Metric and Model Of Hybrid Starmentioning

confidence: 99%

“…Several authors have successfully employed the TK ansatz to develop a realistic and stable model of compact stars, both in the context of General Relativity and of alternative theories of gravity, and it will be explored in detail in the next sections. Recently, we have modelled a charged compact star in f (R, T ) gravity by using the TK metric [98]. In the present work, we have developed a hybrid star model constituted with SQM and normal baryonic matter in Einstein gravity, employing two types of EoSs; a simple linear relation between the radial pressure and the matter density for barynoic matter and a well-established phenomenological MIT bag model EoS in the well-studied TK ansatz background for SQM.…”

Section: Introductionmentioning

confidence: 99%

Model of hybrid star with baryonic and strange quark matter in Tolman-Kuchowicz spacetime

Rej,

Bhar

2022

Preprint

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The purpose of our present work is to investigate some new features of a static anisotropic relativistic hybrid compact star composed of strange quark matter (SQM) in the inner core and normal baryonic matter distribution in the crust. Here we apply the simplest form of the phenomenological MIT bag model equation of state pq = 1 3 (ρq − 4Bg) to correlate the density and pressure of strange quark matter within the stellar interior, whereas radial pressure and matter density due to baryonic matter are connected by the simple linear equation of state pr = αρ − β. In order to obtain the solution of the Einstein field equations, we have used the Tolman-Kuchowicz ansatz [Tolman, Phys Rev 55:364, 1939; Kuchowicz, Acta Phys Pol 33:541, 1968] and further derivation of the arbitrary constants from some physical conditions. Here, we examine our proposed model graphically and analytically in detail for physically plausible conditions. In particular, for this investigation, we have reported on the compact object Her X − 1 [Mass=(0.98 ± 0.12)M ⊙ ; Radius= 8.1 +0.41 −0.41 km] in our paper as a strange quark star candidate. In order to check the physical validity and stability of our suggested model, we have performed various physical tests both analytically and graphically, namely, dynamical equilibrium of applied forces, energy conditions, compactness factor, and surface redshift etc. Finally, we have found that our present model meets all the necessary physical requirements for a realistic model and can be studied for strange quark stars (SQS).

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Charged compact star in f(R, T) gravity in Tolman–Kuchowicz spacetime

Abstract: In this current study, our main focus is on modeling the specific charged compact star SAX J 1808.4-3658 (M = 0.88 $$M_{\odot }$$ M ⊙ , R = 8.9 km) within the framework of $$f(R,\,T)$$ f ( R , T ) modified gravity theory usi… Show more

Cited by 64 publications

References 61 publications

Kuchowicz gravastars in the braneworld formalism

Kuchowicz gravastars in the braneworld formalism

Dark Energy Stars in Tolman-Kuchowicz spacetime in the context of Einstein Gravity

Model of hybrid star with baryonic and strange quark matter in Tolman-Kuchowicz spacetime

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