A supermassive black hole in the galaxy LID-568 has stunned scientists with its voracious feeding behavior, consuming material at a rate over 40 times the Eddington limit. Found in a galaxy from just 1.5 billion years after the Big Bang, this extreme case could offer insight into how early black holes amassed such enormous sizes in such a short time. Led by astronomer Hyewon Suh of Gemini Observatory and NSF’s NOIRLab, a research team discovered this unique black hole using observations from the James Webb Space Telescope (JWST).

Using JWST’s NIRSpec spectrograph, Suh’s team pinpointed the galaxy’s location, confirming its vast distance from Earth. Although the galaxy appears faint from our viewpoint, its brightness at such a distance signals extraordinary intrinsic luminosity. Additionally, they observed powerful outflows from the black hole, characteristic of active feeding as it consumes and expels material into space. This fortunate observation offers a glimpse of super-Eddington processes, which may explain why some black holes in the early universe reached immense sizes so quickly.

The formation of supermassive black holes remains a mystery. One theory posits that these giants may have originated from massive gas clouds collapsing directly into black holes, rather than forming from smaller stellar remnants. Super-Eddington accretion could be another contributing factor, enabling smaller black holes to rapidly gain mass. Suh notes that this “fast-feeding mechanism” above the Eddington limit may explain the mass growth of early black holes regardless of their origin, providing a key piece in solving the puzzle of cosmic evolution.

This discovery not only sheds light on the growth of early black holes but also emphasizes the importance of super-Eddington accretion episodes. As more observations focus on LID-568 and similar galaxies, scientists hope to reveal further clues about the universe’s infancy and how supermassive black holes came to exist so soon after the Big Bang.