On the black hole limit of rotating discs and rings

Kleinwächter, Andreas; Labranche, Hendrick; Meinel, Reinhard

doi:10.1007/s10714-010-1135-9

Cited by 12 publications

(17 citation statements)

References 32 publications

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“…also used in the study of the uncharged disk [21,22,27,28]. This parameter is related to the redshift Z c of a photon emitted at the centre of the disk and measured at infinity via γ = Z c /(1 + Z c ).…”

Section: Parameter Space and Physical Quantitiesmentioning

confidence: 99%

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Gyromagnetic factor of rotating disks of electrically charged dust in general relativity

et al. 2016

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We calculated the dimensionless gyromagnetic ratio ("g-factor") of self-gravitating, uniformly rotating disks of dust with a constant specific charge . These disk solutions to the Einstein-Maxwell equations depend on and a "relativity parameter" γ (0 < γ ≤ 1) up to a scaling parameter. Accordingly, the g-factor is a function g = g(γ, ). The Newtonian limit is characterized by γ 1, whereas γ → 1 leads to a black-hole limit. The g-factor, for all , approaches the values g = 1 as γ → 0 and g = 2 as γ → 1.

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Section: Parameter Space and Physical Quantitiesmentioning

confidence: 99%

“…Based on the algorithm introduced in [27], the authors of [25,26] were able to calculate the solution in terms of a high order post-Newtonian expansion in the parameter γ. In particular, [26] provided strong evidence that, analogous to the uncharged case [28], the limit γ → 1 leads to the extreme Kerr-Newman black hole.…”

Section: Introductionmentioning

confidence: 96%

Gyromagnetic factor of rotating disks of electrically charged dust in general relativity

et al. 2016

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“…Interestingly, it turns out that the power series expansion at γ = 0 could be used to make a statement about the leading order behaviour for the power series expansion at γ = 1. The uncharged case is discussed analytically in [20]. For this purpose we Figure 4: The quantity S Ω in the limit γ → 1 for increasing expansion orders N and for a Páde approximation P [4,16] in √ γ (dashed dotted line) (a), the convergence criterion for increasing n (b) and the coefficient functions |c n | (c).…”

Section: Leading Order Behaviour Close To the Black Hole Limitmentioning

confidence: 99%

On the black hole limit of rotating discs of charged dust

Breithaupt¹,

Liu²,

Meinel³

et al. 2015

Class. Quantum Grav.

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Investigating the rigidly rotating disc of dust with constant specific charge, we find that it leads to an extreme Kerr-Newman black hole in the ultrarelativistic limit. A necessary and sufficient condition for a black hole limit is, that the electric potential in the co-rotating frame is constant on the disc. In that case certain other relations follow. These relations are reviewed with a highly accurate post-Newtonian expansion.Remarkably it is possible to survey the leading order behaviour close to the black hole limit with the post-Newtonian expansion. We find that the disc solution close to that limit can be approximated very well by a "hyperextreme" Kerr-Newman solution with the same gravitational mass, angular momentum and charge.

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“…the constant of integration in (31) is set to zero; it is implied that q > 1. Direct calculations based on coordinate transformations (11), (12) show that for the critical particlẽ…”

Section: A Critical Particlementioning

confidence: 99%

“…For instance, the Bertotti-Robinson space-time and its rotational analogue appear in the processes of different limiting transitions in the context of gravitational thermal ensembles [6] and can be relevant in the context of the AdS/CFT correspondence [7], [8] or the Kerr/CFT one [9]. They are also encountered in many other physical contexts connected with nonlinear electrodynamics [10], conformal mechanics [11], limiting transitions from rapidly rotating discs to black holes [12], etc. Acceleration horizons approximately describe an infinite throat of the extremal Kerr, Reissner-Nordström or Kerr-Newman black holes.…”

Section: Introductionmentioning

confidence: 99%

Acceleration of particles by acceleration horizons

Заславский

2013

Phys. Rev. D

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We consider collision of two particles in the vicinity of the extremal acceleration horizon (charged or rotating) that includes the Bertotti-Robinson space-time and the geometry of the Kerr throat. It is shown that the energy in the centre of mass frame E_{c.m.} can become indefinitely large if parameters of one of the particles are fine-tuned, so the Ba\~nados-Silk-West (BSW) effect manifests itself. There exists coordinate transformation which brings the metric into the form free of the horizon. This leads to some paradox since (i) the BSW effect exists due to the horizon, (ii) E_{c.m.} is a scalar and cannot depend on the frame. Careful comparison of near-horizon trajectories in both frames enables us to resolve this paradox. Although globally the space-time structure of the metrics with acceleration horizons and black holes are completely different, locally the vicinity of the extremal black hole horizon can be approximated by the metric of the acceleration one. The energy of one particle from the viewpoint of the Kruskal observer (or the one obtained from it by finite local boost) diverges although in the stationary frame energies of both colliding particles are finite. This suggests a new explanation of the BSW effect for black holes given from the viewpoint of an observer who crosses the horizon. It is complementary to the previously found explanation from the point of view of a static or stationary observer.Comment: 30 pages. Presentation improved and expanded, Sec. VI and VII and Appendix added. Matches version accepted in PRD. I thank the referee for helping in the improvement of this pape

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On the black hole limit of rotating discs and rings

Cited by 12 publications

References 32 publications

Gyromagnetic factor of rotating disks of electrically charged dust in general relativity

Gyromagnetic factor of rotating disks of electrically charged dust in general relativity

On the black hole limit of rotating discs of charged dust

Acceleration of particles by acceleration horizons

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