Equilibrium configurations of two charged masses in general relativity

Alekseev, G. A.; Belinski, V.

doi:10.1103/physrevd.76.021501

Cited by 45 publications

(98 citation statements)

References 25 publications

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“…The N = 2 Bretón-Manko-Aguilar class of electrostatic solutions [49][50][51][52][53] is spanned by five parameters: two masses M ± , two charges Q ± and the separation of centres d. We focus on the Reissner-Nordström di-hole sub-class, in which both bodies are black holes (Q ± ≤ M ± ); this sub-class includes the MP di-holes (M ± = Q ± ) and Weyl-Bach [54] diholes (Q ± = 0) as special cases. With the exception of the MP cases, the charged black holes are held in equilibrium by a 'Weyl strut' [54], and their horizons appear as 'rods' of coordinate length 2 M 2 ± − Q 2 ± on the symmetry axis, in coordinate system (2).…”

Section: Reissner-nordström Di-holesmentioning

confidence: 99%

“…With the exception of the MP cases, the charged black holes are held in equilibrium by a 'Weyl strut' [54], and their horizons appear as 'rods' of coordinate length 2 M 2 ± − Q 2 ± on the symmetry axis, in coordinate system (2). We examined a two-parameter sub-family: the equal-mass, equal-charge black holes with q = Q ± /M ± and M ± = M , held in equilibrium by a Weyl strut imparting a force [52,53] where σ = 1 − q 2 . The coordinate distance between the horizons is d − 2σM .…”

Section: Reissner-nordström Di-holesmentioning

confidence: 99%

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Stable photon orbits in stationary axisymmetric electrovacuum spacetimes

Dolan

Shipley

2016

Phys. Rev. D

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We investigate the existence and phenomenology of stable photon orbits (SPOs) in stationary axisymmetric electrovacuum spacetimes in four dimensions. First, we review the classification of equatorial circular photon orbits on Kerr-Newman spacetimes in the charge-spin plane. Second, using a Hamiltonian formulation, we show that Reissner-Nordström di-holes (a family encompassing the Majumdar-Papapetrou and Weyl-Bach special cases) admit SPOs, in a certain parameter regime that we investigate. Third, we explore the transition from order to chaos for typical SPOs bounded within a toroidal region around a di-hole, via a selection of Poincaré sections. Finally, for general axisymmetric stationary spacetimes, we show that the Einstein-Maxwell field equations allow for the existence of SPOs in electrovacuum; but not in pure vacuum. * s.dolan@sheffield.ac.uk † joshipley1@sheffield.ac.uk 1 arXiv:1605.07193v2 [gr-qc]

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Section: Reissner-nordström Di-holesmentioning

confidence: 99%

Section: Reissner-nordström Di-holesmentioning

confidence: 99%

Stable photon orbits in stationary axisymmetric electrovacuum spacetimes

Dolan

Shipley

2016

Phys. Rev. D

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“…Recently Belinski and Alekseev [17] obtained an exact two-body solution to the Einstein-Maxwell equations for a Reissner-Nordström black hole in equilibrium with a naked singularity. We have shown in the Appendix that the Belinski-Alekseev solution, once linearized with respect to the mass and charge of the naked singularity, coincides with our solution.…”

Section: Discussionmentioning

confidence: 99%

“…Recently an important progress has been achieved by Belinski and Alekseev [17]. They have obtained an exact two-body solution of the Einstein-Maxwell equations in explicit analytic form for the system consisting of a ReissnerNordström black hole and a naked singularity, by using the monodromy transform approach [18].…”

Section: Introductionmentioning

confidence: 99%

Charged massive particle at rest in the field of a Reissner-Nordström black hole. II. Analysis of the field lines and the electric Meissner effect

2008

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The properties of the electric field of a two-body system consisting of a Reissner-Nordström black hole and a charged massive particle at rest have recently been analyzed in the framework of first order perturbation theory following the standard approach of Regge, Wheeler and Zerilli. In the present paper we complete this analysis by numerically constructing and discussing the lines of force of the "effective" electric field of the sole particle with the subtraction of the dominant contribution of the black hole. We also give the total field due to the black hole and the particle. As the black hole becomes extreme an effect analogous to the Meissner effect arises for the electric field, with the "effective field" lines of the point charge being expelled by the outer horizon of the black hole. This effect existing at the level of test field approximation, i.e. by neglecting the backreaction on the background metric and electromagnetic field due to the particle's mass and charge, is here found also at the complete perturbative level. We point out analogies with similar considerations for magnetic fields by Bičák and Dvořák. We also explicitly show that the linearization of the recently obtained Belinski-Alekseev exact solution coincides with our solution in the Regge-Wheeler gauge. Our solution thus represents a "bridge" between the test field solution, which neglects all the feedback terms, and the exact two-body solution, which takes into account all the non-linearity of the interaction.

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“…In the papers [1][2][3][4][5] the term (1) arose in approximate calculations, but exact solutions are now available to describe the field of two massive charges at rest [9][10][11][12][13][14][15][16], and it should be possible to identify terms like (1) in them. We want here to take one of these solutions [9] and show that it does in fact contain such terms.…”

Section: Introductionmentioning

confidence: 99%