Non-equatorial scalar rings supported by rapidly spinning Gauss-Bonnet black holes

Abstract

Black-hole spacetimes that possess stationary equatorial matter rings are known to exist in general relativity. We here reveal the existence of black-hole spacetimes that support non-equatorial matter rings. In particular, it is proved that rapidly-rotating Kerr black holes in the dimensionless large-spin regime a> acrit= \7+7[13(33)]- 21[13(33)]\/120.78 can support a pair of non-equatorial massive scalar rings which are negatively coupled to the Gauss-Bonnet curvature invariant of the spinning spacetime (here a J/M2 is the dimensionless angular momentum of the central supporting black hole). We explicitly prove that these non-equatorial scalar rings are characterized by the dimensionless functional relation -57+2821[13(133)] 8(1+1- a2)6 ·ημ2 1+ in the large-mass μ Mμ1 regime (here \η<0,μ\ are respectively the non-trivial coupling parameter of the composed Einstein-Gauss-Bonnet-massive-scalar field theory and the proper mass of the supported non-minimally coupled scalar field).

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