Non-linear effects on radiation propagation around a charged compact object

Cuzinatto, R. R.; Melo, C. A. M. de; Vasconcelos, K. C. de; Medeiros, L. G.; Pompeia, P. J.

doi:10.1007/s10509-015-2505-2

Cited by 6 publications

(6 citation statements)

References 57 publications

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“…In figure (12) it can be observed that z massless < z ph < z RN , when we consider z redshift in function of q/q c where q c = M.…”

Section: Born-infeld Black Holementioning

confidence: 97%

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Frequency Shifts of photons emitted from geodesics of nonlinear electromagnetic black holes

López

Olvera

2020

Preprint

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We analyzed the frequency shifts of photons emitted from massive particles that move in stable geodesics around black holes with non-linear electrodynamics. The motion of the photon is modified by an effective metric when the Einstein gravity is coupled with non-linear electrodynamics. The kinematic shifts for photons are modified by the magnetic and electric factors that make the difference between the linear and non-linear electrodynamics. As an illustration, we present the frequency shifts of the photons for black holes with non-linear electrodynamics, two magnetic black holes, and two electric black holes, the Bardeen and Bronnikov black holes for the magnetic charge and the Born-Infeld and Dymnikova black holes for electric charge. These frequency shifts are compared with their linear electromagnetic counterpart.

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“…In figure (12) it can be observed that z massless < z ph < z RN , when we consider z redshift in function of q/q c where q c = M.…”

Section: Born-infeld Black Holementioning

confidence: 97%

“…Also in [12], the non-linear electrodynamics effects on the geodesic deviation and the redshift of photons propagating near spherically symmetric mass and charge distributions are analyzed up to the first-order considering the effective metric.…”

Section: Introductionmentioning

confidence: 99%

Frequency Shifts of photons emitted from geodesics of nonlinear electromagnetic black holes

López

Olvera

2020

Preprint

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“…Nonlinear counterpart of the Maxwell stress tensor causes to deviate the photon geodesics where the photons do not move along the null geodesics. Usually one use an effective metric to study gravitational lensing of the light rays moving on such a charged black holes metric [41][42][43][44]. In the following section we seek effective metric of the ABG black hole for photon trajectories.…”

Section: Abg Space Timementioning

confidence: 99%

“…Furthermore we should point that the nonsingular charged black holes obtained from NEM models in curved space times cause that the photons do not move along null geodesics. As an applicable approach we must be obtain corresponding effective metric for geodesics of moving photons [42][43][44][45] and so study their gravitational lensing. The black hole electric charge has also important effects on final state of the Hawking radiation and switching off effects of a quantum evaporating black hole (see for instance [46]).…”

Section: Introductionmentioning

confidence: 99%

Gravitational Lensing of Charged Ayon-Beato-Garcia Black Holes and Nonlinear Effects of Maxwell Fields

Ghaffarnejad

Amirmojahedi

Niad

2018

Advances in High Energy Physics

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Non-singular Ayon-Beato-Garcia (ABG) spherically symmetric sta tic black hole (BH) with charge to mass ratio q = g 2m is metric solution of Born-Infeld nonlinear Maxwell-Einstein theory. Central region of the BH behaves as (anti-) de Sitter for (|q| > 1) |q| < 1. In case of |q| = 1 the BH central region behaves as Minkowski flat metric. Nonlinear Electromagnetic (NEM) fields counterpart causes to deviate light geodesics and so light rays will forced to move on effective metric. In this paper we study weak and strong gravitational lensing of light rays by seeking affects of NEM fields counterpart on image locations and corresponding magnification. We set our calculations to experimentally observed Sgr A * BH. In short we obtained: For large distances the NEM counterpart is negligible reaching to linear Maxwell fields. The NEM makes enlarge the BH photon sphere radius as linearly by raising |q| > 1 but deceases by raising |q| ≤ 1. Sign of deflection angle of bending light rays is changed in presence of NEM effects with respect to ones obtained in absence of NEM fields. Absolute value of deflection angle raises by increasing |q| → 1. Weak image locations decreases (increases) by raising 0 < |q| < 1 in presence (absence) of NEM fields. By raising the closest distance of the bending light rays weak image locations changes from left (right) to right (left) in absence (presence) of NEM fields. Einstein rings radius and corresponding magnification centroid become larger (smaller) in presence (absence) of NEM fields in case of weak lensing. Angular separation s between the innermost and outermost relativistic images increases (decreases) by increasing 0 < |q| < 1 in absence (presence) of NEM fields. Corresponding magnification r decreases (increases) by raising 0 < |q| < 1 in absence (presence) of NEM fields. s(r) raises (decreases) by increasing |q| >> 1.

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“…Logarithmic and Exponential electrodynamics [6][7][8][9] -and the NLED became a class of electromagnetic theories [10]. This class of theories has applications in several branches of physics being particularly interesting in systems where the NLED are minimally coupled with gravitation as in the cases of charged black holes [11][12][13][14][15][16][17] and cosmology [18][19][20][21][22].…”

Section: Introductionmentioning

confidence: 99%

Constraining Born–Infeld-like nonlinear electrodynamics using hydrogen’s ionization energy

Akmansoy

Medeiros

2018

Eur. Phys. J. C

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In this work, the hydrogen's ionization energy was used to constrain the free parameter b of three BornInfeld-like electrodynamics namely Born-Infeld itself, Logarithmic electrodynamics and Exponential electrodynamics. An analytical methodology capable of calculating the hydrogen ground state energy level correction for a generic nonlinear electrodynamics was developed. Using the experimental uncertainty in the ground state energy of the hydrogen atom, the bound b > 5.37 × 10 20 K V m , where K = 2, 4 √ 2/3 and √ π for the Born-Infeld, Logarithmic and Exponential electrodynamics respectively, was established. In the particular case of Born-Infeld electrodynamics, the constraint found for b was compared with other constraints present in the literature.

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Non-linear effects on radiation propagation around a charged compact object

Cited by 6 publications

References 57 publications

Frequency Shifts of photons emitted from geodesics of nonlinear electromagnetic black holes

Frequency Shifts of photons emitted from geodesics of nonlinear electromagnetic black holes

Gravitational Lensing of Charged Ayon-Beato-Garcia Black Holes and Nonlinear Effects of Maxwell Fields

Constraining Born–Infeld-like nonlinear electrodynamics using hydrogen’s ionization energy

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