The mass gap in five dimensional Einstein–Gauss–Bonnet black holes: a geometrical explanation

Hansraj, C; Goswami, R; Maharaj, S D

doi:10.1088/1361-6382/ad28f8

Class. Quantum Grav.

2024

DOI: 10.1088/1361-6382/ad28f8

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The mass gap in five dimensional Einstein–Gauss–Bonnet black holes: a geometrical explanation

C Hansraj,

R Goswami,

S D Maharaj

Abstract: It is well known that, unlike in higher dimensional general relativity (GR), we cannot have a black hole with an arbitrarily small mass in five dimensional Einstein–Gauss–Bonnet gravity. When we study the dynamical black hole formation via the radiation collapse in the radiating Boulware–Deser spacetime in five dimensions, the central zero mass singularity is weak, conical and naked, and the horizon forms only when a finite amount of matter, that depends on the coupling constant of the Gauss–Bonnet term, falls… Show more

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2024

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Cited by 2 publications

References 66 publications

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General relativistic gravitational induction and causal temperatures

Hakata,

Goswami,

Hansraj

et al. 2024

Class. Quantum Grav.

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In this paper, we describe the process of general relativistic gravitational induction in spherically symmetric spacetimes by defining an energy momentum tensor for the induction process, which is divergence-free and hence conserved. The aforementioned tensor explicitly describes how the matter-free gravity, as measured by the geometrical Weyl curvature, interacts with the matter. This tensor is clearly different from the energy momentum tensor of the standard matter and we transparently show that in spherical symmetry, the Bianchi identities reduce to the conservation laws for these two such energy momentum tensors. Working with a semitetrad covariant formalism in spherically symmetric spacetimes, we then demonstrate the process of constructing a consistent causal thermodynamical picture for the free gravity and matter interaction via the general non-truncated Israel-Stewart heat transport equation. As an illustrative example, we consider the Lemaître-Tolman-Bondi spacetime to highlight the relationship between the shear and the Weyl curvature in determining the inductive heat flux.

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General relativistic gravitational induction and causal temperatures

Hakata,

Goswami,

Hansraj

et al. 2024

Class. Quantum Grav.

View full text Add to dashboard Cite

show abstract

Color flavor locked strange stars in de Rham–Gabadadze–Tolley like massive gravity

Das,

Karmakar,

Debnath

2024

Eur. Phys. J. C

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We investigate Color Flavor Locked (CFL) Strange Stars using the most basic de Rham–Gabadadze–Tolley massive gravity model, which explains the massive graviton in the absence of a ghost propagating mode. In the current study, the compact star model has been achieved by solving the field equations for a static, uncharged sphere (Li et al., in Phys Dark Universe 42: 101308, 2023). Here, we provide some analytical and numerical findings and examine the effects of the massive gravity and anisotropy characteristics on the structure of this stellar object. The modified Tolman–Oppenheimer–Volkoff equation is obtained by taking into account the hydrostatic equilibrium. In order to verify stability of the stellar object, we have taken into account the redshift function and adibatic index. Furthermore, it is observed that the model parameters have a substantial impact on the mass, radius, and compactness of the star object. Finally, our findings provide a possible structure of hypothetical super massive CFL strange stars, which may be placed in the lower “mass-gap” region $$2~M_{\odot }-5~M_{\odot }$$ 2 M ⊙ - 5 M ⊙ and remains stable without collapsing into a black hole corresponding to our considered model parameters.

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The mass gap in five dimensional Einstein–Gauss–Bonnet black holes: a geometrical explanation

Cited by 2 publications

References 66 publications

General relativistic gravitational induction and causal temperatures

General relativistic gravitational induction and causal temperatures

Color flavor locked strange stars in de Rham–Gabadadze–Tolley like massive gravity

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