Inertial forces and photon surfaces in arbitrary spacetimes

Foertsch, Thomas; Haße, W; Perlick, Volker

doi:10.1088/0264-9381/20/21/006

Cited by 31 publications

(46 citation statements)

References 14 publications

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“…We have chosen the standard observers; a different choice would lead to different formulas for the inertial accelerations (19), (20) and (21), but to the same Ψ ± . For the sake of comparison, the reader may consult Nayak and Vishveshwara [20] where the inertial accelerations are calculated with respect to the zero angular momentum observers.…”

Section: Centrifugal and Coriolis Force In The Kerr-newman Spacementioning

confidence: 99%

A Morse-theoretical analysis of gravitational lensing by a Kerr-Newman black hole

Haße

Perlick

2006

Journal of Mathematical Physics

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Consider, in the domain of outer communication M+ of a Kerr-Newman black hole, a point p (observation event) and a timelike curve γ (worldline of light source). Assume that γ (i) has no past end-point, (ii) does not intersect the caustic of the past light-cone of p, and (iii) goes neither to the horizon nor to infinity in the past. We prove that then for infinitely many positive integers k there is a past-pointing lightlike geodesic λ k of (Morse) index k from p to γ, hence an observer at p sees infinitely many images of γ. Moreover, we demonstrate that all lightlike geodesics from an event to a timelike curve in M+ are confined to a certain spherical shell. Our characterization of this spherical shell shows that in the Kerr-Newman spacetime the occurrence of infinitely many images is intimately related to the occurrence of centrifugal-plus-Coriolis force reversal.

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Section: Centrifugal and Coriolis Force In The Kerr-newman Spacementioning

confidence: 99%

A Morse-theoretical analysis of gravitational lensing by a Kerr-Newman black hole

Haße

Perlick

2006

Journal of Mathematical Physics

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“…First we transport it along the curved projected trajectory, then we Lie-transport it up along the congruence as depicted in figure 1 3 . Alternatively, we may in the style of [4], consider the worldsheet spanned by the congruence lines that are crossed by the test particle worldline. On this sheet we can uniquely extend the forward vector t µ , defined along the test particle worldline, into a vector field that is tangent to the sheet, normalized and orthogonal to η µ .…”

Section: The Projected Curvature and Curvature Directionmentioning

confidence: 99%

Inertial forces and the foundations of optical geometry

Jonsson

2005

Class. Quantum Grav.

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Abstract. Assuming a general timelike congruence of worldlines as a reference frame, we derive a covariant general formalism of inertial forces in General Relativity. Inspired by the works of Abramowicz et. al. (see e.g. Abramowicz and Lasota 1997 Class. Quantum Grav. 14 A23-30), we also study conformal rescalings of spacetime and investigate how these affect the inertial force formalism. While many ways of describing spatial curvature of a trajectory has been discussed in papers prior to this, one particular prescription (which differs from the standard projected curvature when the reference is shearing) appears novel. For the particular case of a hypersurface-forming congruence, using a suitable rescaling of spacetime, we show that a geodesic photon is always following a line that is spatially straight with respect to the new curvature measure. This fact is intimately connected to Fermat's principle, and allows for a certain generalization of the optical geometry as will be further pursued in a companion paper (Jonsson and Westman 2006 Class. Quantum Grav. 23 61). For the particular case when the shear-tensor vanishes, we present the inertial force equation in threedimensional form (using the bold face vector notation), and note how similar it is to its Newtonian counterpart. From the spatial curvature measures that we introduce, we derive corresponding covariant differentiations of a vector defined along a spacetime trajectory. This allows us to connect the formalism of this paper to that of Jantzen et. al. (see e.g. Bini et. al. 1997 Int. J. Mod. Phys. D 6 143-98).

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“…These equations hold for all t and allt in R. By considering the special case t =t − R(t) we find R(t) = R t − 2R(t) (11) for allt in R. To ease notation, we drop the tilde in the following. By induction, (11) yields…”

Section: R(t) =R T − R(t)mentioning

confidence: 99%

“…Note that any timelike 2-surface is ruled by two families of lightlike curves; in general, however, these will not be geodesics. Foertsch, Hasse and Perlick [11] have shown that a timelike 2-surface is ruled by two families of lightlike geodesics if and only if its second fundamental form is a multiple of its first fundamental form. In the mathematical literature, such surfaces are called totally umbilic.…”

Section: Observer Fieldsmentioning

confidence: 99%