Retrolensing by a wormhole at deflection anglesπand3π

Abstract: The deflection angle of a light ray can be arbitrarily large near a light sphere. The timesymmetrical shape of light curves of a pair of light rays reflected by a light sphere of a lens object does not depend on the details of the lens object. We consider retrolensing light curves of sunlight with deflection angles π and 3π by an Ellis wormhole, which is the simplest MorrisThorne wormhole. If an Ellis wormhole with a throat parameter a = 10 11 km is 100 pc away from an observer and if the Ellis wormhole, the o… Show more

“…[10], in order to approximate the deflection angle α. As x 0 approaches x m this angle diverges logarithmically, and it can be approximated in the form [10,11] α(x 0 ) = −a 1 log…”

“…The first step in calculating the integral I (x 0 ) that determines the deflection angle α in Eq. (11) Finally, after some calculations (see [11] for the details), the strong deflection limit coefficients take the form…”

“…We follow the method described in Ref. [11], which is in turn an improvement to the one developed in Ref. [10], in order to approximate the deflection angle α.…”

“…Let us apply the general procedure [11], valid for any spherically symmetric and asymptotically flat geometry with a photon sphere, for obtaining the strong deflection limit coefficients c 1 and c 2 appearing in Eq. (15).…”

“…This method, consisting in a logarithmic approximation of the deflection angle for light rays deflecting close to the photon sphere, was introduced for the Schwarzschild black hole [4][5][6][7][8], extended to the Reissner-Nordström geometry [9], and generalized to arbitrary spherically symmetric and asymptotically flat spacetimes [10]. It has been recently improved by simplifying the form to perform the calculations [11]. Within this limit, one can analytically obtain the positions, the magnifications, and the time delays of the relativistic images.…”

Gravitational lensing by a Horndeski black hole

“…[10], in order to approximate the deflection angle α. As x 0 approaches x m this angle diverges logarithmically, and it can be approximated in the form [10,11] α(x 0 ) = −a 1 log…”

“…The first step in calculating the integral I (x 0 ) that determines the deflection angle α in Eq. (11) Finally, after some calculations (see [11] for the details), the strong deflection limit coefficients take the form…”

“…We follow the method described in Ref. [11], which is in turn an improvement to the one developed in Ref. [10], in order to approximate the deflection angle α.…”

“…Let us apply the general procedure [11], valid for any spherically symmetric and asymptotically flat geometry with a photon sphere, for obtaining the strong deflection limit coefficients c 1 and c 2 appearing in Eq. (15).…”

“…This method, consisting in a logarithmic approximation of the deflection angle for light rays deflecting close to the photon sphere, was introduced for the Schwarzschild black hole [4][5][6][7][8], extended to the Reissner-Nordström geometry [9], and generalized to arbitrary spherically symmetric and asymptotically flat spacetimes [10]. It has been recently improved by simplifying the form to perform the calculations [11]. Within this limit, one can analytically obtain the positions, the magnifications, and the time delays of the relativistic images.…”

Gravitational lensing by a Horndeski black hole

Traversable wormholes in $f(R,T)$ gravity

Strong lensing of a regular black hole with an electrodynamics source