Observational signatures of massive black hole formation in the early Universe

• Published in: Nature astronomy Vol. 2; no. 12; pp. 987 - 994
• Main Authors: Barrow, Kirk S. S., Aykutalp, Aycin, Wise, John H.
• Format: Journal Article
• Language: English
• Published: London Nature Publishing Group UK 01.12.2018; Nature Publishing Group
• Subjects: 639/33/34/124; 639/33/34/2810; 639/33/34/861; 639/33/34/865; 639/33/34/867; Accretion; Astronomy; Astrophysics and Cosmology; Black holes; Filters; Physics; Physics and Astronomy; Space telescopes; Star & galaxy formation
• ISSN: 2397-3366; 2397-3366
• DOI: 10.1038/s41550-018-0569-y

Space telescope observations of massive black holes during their formation may be key to understanding the origin of supermassive black holes and high-redshift quasars. To create diagnostics for their detection and confirmation, we study a simulation of a nascent massive ‘direct-collapse’ black hole that induces a wave of nearby massive metal-free star formation, unique to this seeding scenario and to very high redshifts. Here we describe a series of distinct colours and emission line strengths, dependent on the relative strength of star formation and black hole accretion. We predict that the forthcoming James Webb Space Telescope might be able to detect and distinguish a young galaxy that hosts a direct-collapse black hole in this configuration at redshift 15 with as little as a 20,000-second total exposure time across four filters, critical for constraining the seeding mechanisms and early growth rates of supermassive black holes. We also find that a massive seed black hole produces strong, H 2 -dissociating Lyman–Werner radiation. The James Webb Space Telescope may detect and distinguish a young galaxy that hosts a direct-collapse black hole and nearby massive metal-free star formation at redshift 15 with as little as a 20,000-second total exposure time across four filters.