Application of GBT theorem for Gravitational deflection of light by Compact Objects

Authors

DOI:

https://doi.org/10.26577/RCPh.2023.v84.i1.02
        221 114

Keywords:

GBT theorem, deflection of light, , Compact Objects

Abstract

One of the most renowned classical experiments that verifies the curved nature of space-time geometry is the bending of light. This phenomenon is extensively discussed in most textbooks on general relativity, with a clear and comprehensive explanation provided.

In this study, we employ the material medium approach to determine the refractive index associated with the gravitational field of a compact object with a quadrupole moment. Our research presents a method for calculating the gravitational deflection angle for compact objects by utilizing the refractive index and the GBT theorem for an isotropic metric. This method is particularly important because it allows for the calculation of the deflection angle for both light and relativistic particles. The material medium approach enables us to consider the compact object's gravitational field as a medium with a refractive index. By applying this approach, we establish a relationship between the refractive index and the quadrupole moment of the compact object. We then utilize this relationship to calculate the deflection angle of light and relativistic particles.

References

1 K. Jusufi, Physical Review D, 98, 064017, 6–15 (2018).

2 G.W. Gibbons, M.C. Werner, General Relativity and Quantum Cosmology, 25, 235009, 10 (2008).

3 F. Frutos-Alfaro, H. Quevedo, P.A. Sanchez, Royal Society Open Science, 5(5), 170826 (2018): p. 16.

4 S. Toktarbay, H. Quevedo, M. Abishev, A. Muratkhan, European Physical Journal C, 82(4), 382 (2022).

5 M. Abishev, N. Beissen, F. Belissarova, K. Boshkayev, A. Mansurova, A. Muratkhan, H. Quevedo, S. Toktarbay, International Journal of Modern Physics D, 30(13), 2150096, 18 (2021).

6 A. Allahyari, H. Firouzjahi, B. Mashhoon, Physical Review D, 99, 044005, 4–15 (2018).

7 A.K. Sen, Astrophysics, 53(4), 560–569 (2010).

8 S. Roy, A. Sen, General Relativity and Quantum Cosmology, 2, 360 (2015).

9 E. Fischbach, B.S. Freeman, Physical Review D, 22, 2950–2952 (1980).

10 N. Beissen, D. Utepova, M. Abishev, H. Quevedo, M. Khassanov, S. Toktarbay, Symmetry, 15(3), 614 (2023).

11 J. Evans, K. Kanti Nandi, A. Islam, General Relativity and Gravitation., 28, 413–439 (1996).

12 J. Evans, K. Kanti Nandi, A. Islam, American Journal of Physics, 64, 1404–1415 (1996).

13 X.H. Ye, Q. Lin, Journal of Optics A: Pure and Applied Optics, 10, 075001 (2008).

14 J.Nazrul Islam, Rotating Fields in General Relativity, (Cambridge University Press: Cambridge, UK, 2009).

15 S. Roy, A.K. Sen, Journal of Physics: Conference Series, 1, 012002, 1330 (2019).

16 R.H. Boyer, R.W. Lindquist, Journal of Mathematical Physics, 8, 265–281 (1967).

Downloads

How to Cite

Beissen, N., Utepova, D., Muratkhan, A., Orazymbet, A., Khassanov, M., & Toktarbay, S. (2023). Application of GBT theorem for Gravitational deflection of light by Compact Objects. Recent Contributions to Physics (Rec.Contr.Phys.), 84(1), 15–21. https://doi.org/10.26577/RCPh.2023.v84.i1.02

Issue

Section

Theoretical Physics. Nuclear and Elementary Particle Physics. Astrophysics

Most read articles by the same author(s)