Black hole evaporation in Hořava–Lifshitz gravity

Xu, Hao; Ong, Yen Chin

doi:10.1140/epjc/s10052-020-8249-3

Cited by 27 publications

(41 citation statements)

References 55 publications

(65 reference statements)

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“…Also, in the cases D = 4, 5 there always have remnants, while in the cases D 6 that all the black holes will evaporate in a finite time. This phenomenon is quite similar to the Hořava-Lifshitz case [23], which also has the dimensional dependent evaporation behavior.…”

Section: Discussionsupporting

confidence: 72%

“…If we obtain the impact factor b c , we can get the Hawking emission rate in D-dimensional spacetime according to Stefan-Boltzmann law, yields [10,21,23,64,65]…”

Section: Black Hole Evaporation In Dmentioning

confidence: 99%

“…This is because although the black hole may have infinite initial mass, the temperature, and also the particles' emission power, are also divergent, thus the infinite amount of mass can be evaporated away in a finite time. The study on black holes evaporation in asymptotically AdS spacetimes have been extended to many different backgrounds, such as Lovelock gravity [21], Conformal (Weyl) Gravity [22], Hořava-Lifshitz gravity [23], and dRGT massive gravity [24], etc.…”

Section: Introductionmentioning

confidence: 99%

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Hawking evaporation of Einstein–Gauss–Bonnet AdS black holes in $$D\geqslant 4$$ dimensions

2021

Eur. Phys. J. C

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Einstein–Gauss–Bonnet theory is a string-generated gravity theory when approaching the low energy limit. By introducing the higher order curvature terms, this theory is supposed to help to solve the black hole singularity problem. In this work, we investigate the evaporation of the static spherically symmetric neutral AdS black holes in Einstein–Gauss–Bonnet gravity in various spacetime dimensions with both positive and negative coupling constant $$\alpha $$ α . By summarizing the asymptotic behavior of the evaporation process, we find the lifetime of the black holes is dimensional dependent. For $$\alpha >0$$ α > 0 , in $$D\geqslant 6$$ D ⩾ 6 cases, the black holes will be completely evaporated in a finite time, which resembles the Schwarzschild-AdS case in Einstein gravity. While in $$D=4,5$$ D = 4 , 5 cases, the black hole lifetime is always infinite, which means the black hole becomes a remnant in the late time. Remarkably, the cases of $$\alpha >0, D=4,5$$ α > 0 , D = 4 , 5 will solve the terminal temperature divergent problem of the Schwarzschild-AdS case. For $$\alpha <0$$ α < 0 , in all dimensions, the black hole will always spend a finite time to a minimal mass corresponding to the smallest horizon radius $$r_{min}=\sqrt{2|\alpha |}$$ r min = 2 | α | which coincide with an additional singularity. This implies that there may exist constraint conditions to the choice of coupling constant.

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Section: Discussionsupporting

confidence: 72%

“…If we obtain the impact factor b c , we can get the Hawking emission rate in D-dimensional spacetime according to Stefan-Boltzmann law, yields [10,21,23,64,65]…”

Section: Black Hole Evaporation In Dmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Hawking evaporation of Einstein–Gauss–Bonnet AdS black holes in $$D\geqslant 4$$ dimensions

2021

Eur. Phys. J. C

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“…The motivation behind such a geometrically extended gravity is to address the late time cosmic phenomena issue. Xu et al [22] also suggested the Weyl type f (Q, T ) gravity and its cosmological implications. Zia et al [23] have obtained the cosmological model in f (Q, T ) gravity applying the energy conservation equation.…”

Section: Introductionmentioning

confidence: 99%

Model parameters in the context of late time cosmic acceleration in $f(Q,T)$ gravity

Pati,

Mishra,

Tripathy

2021

Preprint

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The dynamical aspects of some accelerating models are investigated in the framework of an extension of symmetric teleparllel gravity dubbed as f (Q, T ) gravity. In this gravity theory, the usual Ricci tensor in the geometrical action is replaced by a functional f (Q, T ) where Q is the non-metricity and T is the trace of the energy-momentum tensor. Two different functional forms are considered in the present work. In order to model the Universe, we have considered a signature flipping deceleration parameter simulated by a hybrid scale factor (HSF). The dynamical parameters of the model are derived and analysed. We discuss the role of the parameter space in getting viable cosmological models. It is found that, the models may be useful as suitable geometrical alternatives to the usual dark energy approach.

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“…After that, Yixin et al [33,34] introduced a symmetric teleparallel gravity extension based on the coupling between non-metricity Q and the trace of the energy-momentum tensor T , i.e., considering an arbitrary function f (Q, T ) in the gravitational action. Using some functional forms of f (Q, T ), some works in this modified gravity look at cosmological models and rapid expansion of the universe.…”

Section: Introductionmentioning

confidence: 99%

Constraining effective equation of state in f(Q, T) gravity

2021

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New high-precision observations are now possible to constrain different gravity theories. To examine the accelerated expansion of the Universe, we used the newly proposed f(Q, T) gravity, where Q is the non-metricity, and T is the trace of the energy–momentum tensor. The investigation is carried out using a parameterized effective equation of state with two parameters, m and n. We have also considered the linear form of $$f(Q,T)= Q+bT$$ f ( Q , T ) = Q + b T , where b is constant. By constraining the model with the recently published 1048 Pantheon sample, we were able to find the best fitting values for the parameters b, m, and n. The model appears to be in good agreement with the observations. Finally, we analyzed the behavior of the deceleration parameter and equation of state parameter. The results support the feasibility of f(Q, T) as a promising theory of gravity, illuminating a new direction towards explaining the Universe dark sector.

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Black hole evaporation in Hořava–Lifshitz gravity

Cited by 27 publications

References 55 publications

Hawking evaporation of Einstein–Gauss–Bonnet AdS black holes in $$D\geqslant 4$$ dimensions

Hawking evaporation of Einstein–Gauss–Bonnet AdS black holes in $$D\geqslant 4$$ dimensions

Model parameters in the context of late time cosmic acceleration in $f(Q,T)$ gravity

Constraining effective equation of state in f(Q, T) gravity

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