Five dimensional rotating and Quintessence black hole and their hypershadows

Abstract

We present a new five-dimensional rotating quintessence black hole solution. To obtain this, we employ the 5D version of the Janis Newman algorithm, which incorporates the Hopf bifurcation. The variation of the quintessence parameter wq causes the geometry to transition from a regular rotating universe surrounded by a cosmological horizon to a singular rotating geometry, which can represent a naked singularity, a singular extremal black hole, or a singular black hole with both an inner and an outer (event) horizon. We have also determined the properties of the ergosphere. For the study of the shadow, we followed a novel approach in which the 2D shadow observed by humans corresponds to cross sections of the 3D shadow. We analyzed how quintessence affects both the size and shape of the black hole shadow, showing that increasing the quintessence strength reduces the shadow radius, contrary to the known results in 4D. We also propose a speculative methodology to test the shadow behavior in five dimensional scenarios, in light of the constraints provided by the Event Horizon Telescope (EHT) concerning the shadow of the four-dimensional supermassive black hole M87. We identify scenarios in which the theoretical 5D results could be consistent with these observational constraints. We have also tested the circularity deviation of our shadows, finding that the results satisfy the bound C ≤ 0.1 both in the case with quintessence and in the limiting case without quintessence. Finally, we determine the energy conditions required to support the solution.

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