Key points are not available for this paper at this time.
Recently, the Event Horizon Telescope (EHT) achieved the realization of an image of the supermassive black hole Sgr~A^ showing an angular shadow diameter D= 48. 7 7 as and the fractional deviation = -0. 08^+0. 09-₀. ₀₉~ (VLTI), -0. 04^+0. 09-₀. ₁₀~ (Keck), alongside the earlier image of M87^ with angular diameter D=42 3 as, deviation =-0. 01^+0. 17-₀. ₁₇ and deviations from circularity estimated to be C 10\%. In addition, the shadow radii are assessed within the ranges 3. 38 rₒM 6. 91 for M87^ and 3. 85 rₒM 5. 72 as well as 3. 95 rₒM 5. 92 for Sgr~A^ using the Very Large Telescope Interferometer (VLTI) and Keck observatories, respectively. These values are provided with 1- and 2- measurements. Such realizations can unveil a better comprehension of gravitational physics at the horizon scale. In this paper, we use the EHT observational results for M87^ and Sgr~A^ to elaborate the constraints on parameters of accelerating black holes with a cosmological constant. Concretely, we utilize the mass and distance of both black holes to derive the observables associated with the accelerating black hole shadow. First, we compare our findings with observed quantities such as angular diameter, circularity, shadow radius, and the fractional deviation from the M87^ data. This comparison reveals constraints within the acceleration parameter and the cosmological constant. . . Lastly, one cannot rule out the possibility of the negative values for the cosmological constant on the emergence of accelerated black hole solutions within the context of minimal gauged supergravity. . .
Chakhchi et al. (Thu,) studied this question.