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Testing Strong Gravitational Lensing Effects of Supermassive Compact Objects with Regular Spacetimes

Jitendra Kumar, Shafqat Ul Islam, Sushant G. Ghosh

2022The Astrophysical Journal54 citationsDOIOpen Access PDF

Abstract

Abstract We compare and contrast gravitational lensing, in the strong field limit, by the photon sphere in spherically symmetric regular electrically charged (REC) black holes (0 < b ≤ b E ) and with those by corresponding REC no-horizon spacetimes ( b > b E ). Here, b is an additional parameter due to the charge and the value b = b E ≈ 0.226 corresponds to an extremal black hole with degenerate horizons. Interestingly, the spacetime admits a photon sphere for 0 < b ≤ b P ≈ 0.247 and an anti-photon sphere only for b E < b ≤ b P . With no-horizon spacetime, images by lensing from the inside of the photon sphere ( u < u ps ) can also appear. Interestingly, for the case of u < u ps the deflection angle α D increases with u . We analyze the lensing observables by modeling compact objects Sgr A*, M87*, NGC 4649, and NGC 1332 as black holes and no-horizon spacetimes. The angular position θ ∞ and photon sphere radius x ps decrease with increasing parameter b . Our findings suggest that the angular separations ( s ) and magnification ( r ) of relativistic images inside the photon sphere may be higher than those outside. Moreover, the time delay for Sgr A* and M87* can reach ∼8.8809 and ∼12,701.8 minutes, respectively, at b = 0.2, deviating from Schwarzschild black holes by ∼2.615 and ∼4677 minutes. These deviations are insignificant for Sgr A* because it is too small, but they are sufficient for astronomical observation of M87* and some other black holes. With EHT bounds on the θ sh of Sgr A* and M87* within the 1 σ region, placing bounds on the parameter b , our analysis concludes that REC black holes agree with the EHT results in finite space, whereas the corresponding REC no-horizon spacetimes are completely ruled out.

Topics & Concepts

PhysicsPhoton sphereSchwarzschild radiusSupermassive black holeAstrophysicsGravitational lensStrong gravitational lensingBlack hole (networking)PhotonAngular diameterStarsGalaxyCharged black holeQuantum mechanicsRedshiftAccretion (finance)Computer networkComputer scienceLink-state routing protocolRouting protocolRouting (electronic design automation)Astrophysical Phenomena and ObservationsPulsars and Gravitational Waves ResearchAstrophysics and Cosmic Phenomena
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