Papers
Topics
Authors
Recent
Detailed Answer
Quick Answer
Concise responses based on abstracts only
Detailed Answer
Well-researched responses based on abstracts and relevant paper content.
Custom Instructions Pro
Preferences or requirements that you'd like Emergent Mind to consider when generating responses
Gemini 2.5 Flash
Gemini 2.5 Flash 75 tok/s
Gemini 2.5 Pro 51 tok/s Pro
GPT-5 Medium 20 tok/s Pro
GPT-5 High 18 tok/s Pro
GPT-4o 95 tok/s Pro
Kimi K2 193 tok/s Pro
GPT OSS 120B 467 tok/s Pro
Claude Sonnet 4 37 tok/s Pro
2000 character limit reached

Deflection of light rays in a moving medium around a spherically symmetric gravitating object (2403.16842v2)

Published 25 Mar 2024 in gr-qc

Abstract: In most analytical studies of light ray propagation in curved spacetimes around a gravitating object surrounded by a medium, it is assumed that the medium is a cold nonmagnetized plasma. The distinctive feature of this environment is that the equations of motion of the rays are independent of the plasma velocity, which, however, is not the case in other media. In this paper, we consider the deflection of light rays propagating near a spherically symmetric gravitating object in a moving dispersive medium given by a general refractive index. The deflection is studied when the motion of the medium is defined either as a radially falling onto a gravitating object (e.g., black hole), or rotating in the equatorial plane. For both cases the deflection angles are obtained. These examples demonstrate that fully analytic expressions can be obtained if the Hamiltonian for the rays takes a rather general form as a polynomial in a given momentum component. The general expressions are further applied to three specific choices of refractive indices and these cases are compared. Furthermore, the light rays propagating around a gravitating object surrounded by a generally moving medium are further studied as a small perturbation of the cold plasma model. The deflection angle formula is hence expressed as a sum of zeroth and first order components, where the zeroth order term corresponds to the known cold plasma case and the first order correction can be interpreted as caused by small difference in the refractive index compared to the cold plasma. The results presented in this paper allow to describe the effects caused by the motion of a medium and thus go beyond cold nonmagnetized plasma model.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (68)
  1. C. M. Will, The 1919 measurement of the deflection of light, Classical and Quantum Gravity 32, 124001 (2015).
  2. E. Goldoni and L. Stefanini, A century of light-bending measurements: bringing solar eclipses into the classroom, Physics Education 55, 045009 (2020).
  3. P. Schneider, J. Ehlers, and E. E. Falco, Gravitational Lenses (Springer-Verlag Berlin Heidelberg, 1992).
  4. R. D. Blandford and R. Narayan, Cosmological applications of gravitational lensing, Annual Review of Astronomy and Astrophysics 30, 311 (1992).
  5. J. Wambsganss, Gravitational lensing in astronomy, Living Reviews in Relativity 1, 12 (1998).
  6. M. Bartelmann, Gravitational lensing, Classical and Quantum Gravity 27, 233001 (2010).
  7. S. Dodelson, Gravitational Lensing (Cambridge University Press, Cambridge, UK, 2017).
  8. A. B. Congdon and C. R. Keeton, Principles of Gravitational Lensing: Light Deflection as a Probe of Astrophysics and Cosmology (2018).
  9. J. L. Synge, Relativity: The General Theory (North-Holland Publishing Company, Amsterdam, 1960).
  10. J. Bičák and P. Hadrava, General-relativistic radiative transfer theory in refractive and dispersive media., Astronomy and Astrophysics 44, 389 (1975).
  11. R. A. Breuer and J. Ehlers, Propagation of high-frequency electromagnetic waves through a magnetized plasma in curved space-time. I, Proceedings of the Royal Society of London Series A 370, 389 (1980).
  12. R. A. Breuer and J. Ehlers, Propagation of high-frequency electromagnetic waves through a magnetized plasma in curved space-time. II - Application of the asymptotic approximation, Proceedings of the Royal Society of London Series A 374, 65 (1981a).
  13. R. A. Breuer and J. Ehlers, Propagation of electromagnetic waves through magnetized plasmas in arbitrary gravitational fields, Astronomy and Astrophysics 96, 293 (1981b).
  14. S. Kichenassamy and R. A. Krikorian, Relativistic radiation transport in dispersive media, Phys. Rev. D 32, 1866 (1985).
  15. R. Kulsrud and A. Loeb, Dynamics and gravitational interaction of waves in nonuniform media, Phys. Rev. D 45, 525 (1992).
  16. R. A. Krikorian, Light rays in gravitating and refractive media: A comparison of the field to particle and Hamiltonian approaches, Astrophysics 42, 338 (1999).
  17. A. Broderick and R. Blandford, Covariant magnetoionic theory – I. Ray propagation, Monthly Notices of the Royal Astronomical Society 342, 1280 (2003a).
  18. A. Broderick and R. Blandford, General Relativistic Magnetoionic Theory, Astrophysics and Space Science 288, 161 (2003b).
  19. A. Broderick and R. Blandford, Covariant magnetoionic theory – II. Radiative transfer, Monthly Notices of the Royal Astronomical Society 349, 994 (2004).
  20. D. O. Muhleman, R. D. Ekers, and E. B. Fomalont, Radio interferometric test of the general relativistic light bending near the sun, Phys. Rev. Lett.  24, 1377 (1970).
  21. D. O. Muhleman and I. D. Johnston, Radio propagation in the solar gravitational field, Phys. Rev. Lett.  17, 455 (1966).
  22. P. V. Bliokh and A. A. Minakov, Gravitational lenses (Naukova Dumka, Kiev, 1989).
  23. G. S. Bisnovatyi-Kogan and O. Y. Tsupko, Gravitational lensing in a non-uniform plasma, Monthly Notices of the Royal Astronomical Society 404, 1790 (2010).
  24. V. S. Morozova, B. J. Ahmedov, and A. A. Tursunov, Gravitational lensing by a rotating massive object in a plasma, Astrophysics and Space Science 346, 513 (2013).
  25. O. Y. Tsupko and G. S. Bisnovatyi-Kogan, Gravitational lensing in plasma: Relativistic images at homogeneous plasma, Phys. Rev. D 87, 124009 (2013).
  26. V. Perlick, O. Y. Tsupko, and G. S. Bisnovatyi-Kogan, Influence of a plasma on the shadow of a spherically symmetric black hole, Phys. Rev. D 92, 104031 (2015).
  27. A. Rogers, Frequency-dependent effects of gravitational lensing within plasma, Monthly Notices of the Royal Astronomical Society 451, 17 (2015).
  28. A. Rogers, Escape and trapping of low-frequency gravitationally lensed rays by compact objects within plasma, Monthly Notices of the Royal Astronomical Society 465, 2151 (2017b).
  29. A. Rogers, Gravitational lensing of rays through the levitating atmospheres of compact objects, Universe 3, 3 (2017c).
  30. V. Perlick and O. Y. Tsupko, Light propagation in a plasma on Kerr spacetime: Separation of the Hamilton-Jacobi equation and calculation of the shadow, Phys. Rev. D 95, 104003 (2017).
  31. V. Perlick and O. Y. Tsupko, Light propagation in a plasma on Kerr spacetime. II. Plasma imprint on photon orbits, Physical Review D (accepted)  (2024), arXiv:2311.10615.
  32. G. Crisnejo, E. Gallo, and K. Jusufi, Higher order corrections to deflection angle of massive particles and light rays in plasma media for stationary spacetimes using the Gauss-Bonnet theorem, Phys. Rev. D 100, 104045 (2019a).
  33. B. Bezděková, V. Perlick, and J. Bičák, Light propagation in a plasma on an axially symmetric and stationary spacetime: Separability of the Hamilton-Jacobi equation and shadow, Journal of Mathematical Physics 63, 092501 (2022).
  34. B. Bezděková and J. Bičák, Light deflection in plasma in the Hartle-Thorne metric and in other axisymmetric spacetimes with a quadrupole moment, Physical Review D 108, 084043 (2023).
  35. G. Crisnejo and E. Gallo, Weak lensing in a plasma medium and gravitational deflection of massive particles using the Gauss-Bonnet theorem. A unified treatment, Phys. Rev. D 97, 124016 (2018).
  36. G. Crisnejo, E. Gallo, and A. Rogers, Finite distance corrections to the light deflection in a gravitational field with a plasma medium, Phys. Rev. D 99, 124001 (2019b).
  37. G. Crisnejo, E. Gallo, and J. R. Villanueva, Gravitational lensing in dispersive media and deflection angle of charged massive particles in terms of curvature scalars and energy-momentum tensor, Phys. Rev. D 100, 044006 (2019c).
  38. X. Er and S. Mao, Effects of plasma on gravitational lensing, Monthly Notices of the Royal Astronomical Society 437, 2180 (2014).
  39. X. Er and S. Mao, The effects of plasma on the magnification and time delay of strongly lensed fast radio bursts, Monthly Notices of the Royal Astronomical Society 516, 2218 (2022).
  40. T. Kimpson, K. Wu, and S. Zane, Spatial dispersion of light rays propagating through a plasma in Kerr space-time, Monthly Notices of the Royal Astronomical Society 484, 2411 (2019a).
  41. T. Kimpson, K. Wu, and S. Zane, Pulsar timing in extreme mass ratio binaries: a general relativistic approach, Monthly Notices of the Royal Astronomical Society 486, 360 (2019b).
  42. V. Perlick and O. Y. Tsupko, Calculating black hole shadows: Review of analytical studies, Physics Reports 947, 1 (2022).
  43. H. Yan, Influence of a plasma on the observational signature of a high-spin Kerr black hole, Phys. Rev. D 99, 084050 (2019).
  44. A. Chowdhuri and A. Bhattacharyya, Shadow analysis for rotating black holes in the presence of plasma for an expanding universe, Phys. Rev. D 104, 064039 (2021).
  45. J. Badía and E. F. Eiroa, Shadows of rotating Einstein-Maxwell-dilaton black holes surrounded by a plasma, Phys. Rev. D 107, 124028 (2023).
  46. Q. Li, Y. Zhu, and T. Wang, Gravitational effect of plasma particles on the shadow of Schwarzschild black holes, European Physical Journal C 82, 2 (2022).
  47. G. Briozzo, E. Gallo, and T. Mädler, Shadows of rotating black holes in plasma environments with aberration effects, Phys. Rev. D 107, 124004 (2023).
  48. Y. Huang, Y.-P. Dong, and D.-J. Liu, Revisiting the shadow of a black hole in the presence of a plasma, International Journal of Modern Physics D 27, 1850114-239 (2018).
  49. K. Kobialko, I. Bogush, and D. Gal’tsov, Black hole shadows of massive particles and photons in plasma, Phys. Rev. D 109, 024060 (2024).
  50. K. Schulze-Koops, V. Perlick, and D. J. Schwarz, Sachs equations for light bundles in a cold plasma, Classical and Quantum Gravity 34, 215006 (2017).
  51. M. Sárený and V. Balek, Effect of black hole-plasma system on light beams, General Relativity and Gravitation 51, 141 (2019).
  52. S. G. Turyshev and V. T. Toth, Diffraction of light by plasma in the solar system, Journal of Optics 21, 045601 (2019a).
  53. S. G. Turyshev and V. T. Toth, Diffraction of light by the gravitational field of the Sun and the solar corona, Phys. Rev. D 99, 024044 (2019b).
  54. J. Wagner and X. Er, Plasma lensing in comparison to gravitational lensing – Formalism and degeneracies, arXiv e-prints , arXiv:2006.16263 (2020).
  55. O. Y. Tsupko and G. S. Bisnovatyi-Kogan, Hills and holes in the microlensing light curve due to plasma environment around gravitational lens, Monthly Notices of the Royal Astronomical Society 491, 5636 (2020).
  56. J. Sun, X. Er, and O. Y. Tsupko, Binary microlensing with plasma environment - star and planet, Monthly Notices of the Royal Astronomical Society 520, 994 (2023).
  57. X. Er, Y.-P. Yang, and A. Rogers, The effects of plasma lensing on the inferred dispersion measures of fast radiobursts, Astrophys. J.  889, 158 (2020).
  58. K. Matsuno, Light deflection by squashed Kaluza-Klein black holes in a plasma medium, Phys. Rev. D 103, 044008 (2021).
  59. A. Guerrieri and M. Novello, Photon propagation in a material medium on a curved spacetime, Classical and Quantum Gravity 39, 245008 (2022).
  60. P. Chainakun, A. Watcharangkool, and A. J. Young, Effects of the refractive index of the X-ray corona on the emission lines in AGNs, Monthly Notices of the Royal Astronomical Society 512, 728 (2022).
  61. P. Kumar and P. Beniamini, Gravitational lensing in the presence of plasma scattering with application to Fast Radio Bursts, Monthly Notices of the Royal Astronomical Society 520, 247 (2023).
  62. G. S. Bisnovatyi-Kogan and O. Y. Tsupko, Time delay induced by plasma in strong lens systems, Monthly Notices of the Royal Astronomical Society 524, 3060 (2023).
  63. G. Briozzo and E. Gallo, Analytical expressions for pulse profile of neutron stars in plasma environments, European Physical Journal C 83, 165 (2023).
  64. O. Y. Tsupko, Deflection of light rays by a spherically symmetric black hole in a dispersive medium, Phys. Rev. D 103, 104019 (2021).
  65. A. Addazi et al., Quantum gravity phenomenology at the dawn of the multi-messenger era—A review, Prog. Part. Nucl. Phys. 125, 103948 (2022), arXiv:2111.05659 [hep-ph] .
  66. C. Pfeifer, Redshift and lateshift from homogeneous and isotropic modified dispersion relations, Phys. Lett. B 780, 246 (2018), arXiv:1802.00058 [gr-qc] .
  67. D. Läänemets, M. Hohmann, and C. Pfeifer, Observables from spherically symmetric modified dispersion relations, International Journal of Geometric Methods in Modern Physics 19, 2250155-60 (2022).
  68. C. W. Misner, K. S. Thorne, and J. A. Wheeler, Gravitation (W. H. Freeman, San Francisco, 1973).
Citations (2)
View on Semantic Scholar

Summary

We haven't generated a summary for this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Summarize Now
List To Do Tasks Checklist Streamline Icon: https://streamlinehq.com

Collections

Sign up for free to add this paper to one or more collections.

User Circle Single Streamline Icon: https://streamlinehq.com Sign Up
Lightbulb On Streamline Icon: https://streamlinehq.com

Continue Learning

We haven't generated follow-up questions for this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Generate Now
X Twitter Logo Streamline Icon: https://streamlinehq.com

Tweets

Don't miss out on important new AI/ML research

See which papers are being discussed right now on X, Reddit, and more:

Explore Trending Papers

“Emergent Mind helps me see which AI papers have caught fire online.”

Philip

Philip

Creator, AI Explained on YouTube