Shadow and deflection angle Reissner – Nordstrom blackhole with cosmological constant in a dark matter fluid
This study derives and calculates the shadow and the deflection angles of Reissner Nordstrom black hole with the cosmological constant in a dark matter fluid. In the premise of shadow, it is evident that at the observer's current position on Earth, the difference between the black hole shadow i...
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| Format: | text |
| Language: | English |
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Animo Repository
2022
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| Online Access: | https://animorepository.dlsu.edu.ph/etdm_physics/6 https://animorepository.dlsu.edu.ph/cgi/viewcontent.cgi?article=1005&context=etdm_physics |
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| Institution: | De La Salle University |
| Language: | English |
| Summary: | This study derives and calculates the shadow and the deflection angles of Reissner Nordstrom black hole with the cosmological constant in a dark matter fluid. In the premise of shadow, it is evident that at the observer's current position on Earth, the difference between the black hole shadow in the co-moving and static reference frame is unnoticeable. It shows that the observer is far from the cosmic horizon. The deviation between the two observers requires a susceptible device to detect the difference in the shadow. Using the data from EHT, the calculation shows that the model in this study could retrieve the measured shadow of Sagittarius A* (Sgr A*) by varying the charge $Q$ and dark matter parameter $\lambda$. However, Messier 87* (M87*) cannot retrieve the value by variation of parameters, $Q$, and $\lambda$, but the results are still a good approximation.
The strong deflection produces a non-physical result at $r \ge 2r_{ps}$. It shows that when the ratio of impact parameter of the closest approach and critical impact parameter significantly deviates from 1, the results are non-physical. As the values of the charge, $Q$, and dark matter fluid, $\lambda$, increase the strong deflection angle increases. In the case of $Q_{M87*} = Q_{Sgr.A*}$ and $\lambda_{M87*} = \lambda_{Sgr.A*}$ the strong deflection for M87* and Sgr. A* at a similar closest approach, $r_{0}$ is approximately equal. It is due to a small difference in the order of magnitude for M87* and Sgr. A*.
Weak deflection calculation using the Gauss-Bonnet theorem works in the region far from the black hole. The impact parameter is a scaled value of the black hole mass. Though the increase in charge, $Q$, and dark matter, $\lambda$ at this region is not that significant compared to the near blackhole case. Applying the conditions $Q_{M87*} = Q_{Sgr.A*}$ and $\lambda_{M87*} = \lambda_{Sgr.A*}$ the weak deflection angle at same impact parameter for M87* and Sgr. A* is significantly the same due to the small difference in the order of magnitude for M87* and Sgr. A*.
The dark matter fluid, $\lambda$ shrinks the shadow, photon sphere, and deflection angles while the charge, on the other hand, has fewer effects on the deflection angles but significantly affects black hole shadows. |
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