期刊
PHYSICAL REVIEW D
卷 101, 期 12, 页码 -出版社
AMER PHYSICAL SOC
DOI: 10.1103/PhysRevD.101.124051
关键词
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资金
- Royal Society, UK, via Royal Society University Research Fellowship [UF160547]
- Royal Society Research [RGF\R1\180073]
- Leibniz Supercomputing Center via PRACE [2018194669]
- DiRAC Consortium via STFC DiRAC [ACTP186, ACDP191, ACSP218]
- STFC [ST/T001569/1, ST/R000832/1, ST/V002635/1, ST/T00049X/1, ST/M007618/1, ST/R001049/1, ST/T001348/1, ST/L000636/1, ST/T001550/1, ST/J005673/1, ST/P000673/1, ST/P002447/1, ST/M006530/1, ST/R001014/1, ST/P003400/1, ST/K00333X/1, ST/R00689X/1, ST/T001372/1, ST/V002384/1, ST/M007065/1, ST/V002376/1, ST/M007006/1, ST/S003762/1, ST/R001006/1, ST/S003916/1, ST/M007073/1, ST/M006948/1] Funding Source: UKRI
Black holes have turned into cosmic laboratories to search for ultralight scalars by virtue of the superradiant instability. In this paper we present a detailed study of the impact of the superradiant evolution on the black hole shadow and investigate the exciting possibility to exploit it with future observations of very long baseline interferometry. We simulated the superradiant evolution numerically, in the adiabatic regime, and derived analytic approximations modeling the process. Driven by superradiance, we evolve the black hole shadow diameter and (i) find that it can change by a few mu as, just below the current resolution of the Event Horizon Telescope, albeit on timescales that are longer than realistic observation times; (ii) show that the shadow diameter can either shrink or grow; and (iii) explore in detail how the shadow's end state is determined by the initial parameters and coupling.
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