Login / Signup

A small and vigorous black hole in the early Universe.

Roberto MaiolinoJan ScholtzJoris WitstokStefano CarnianiFrancesco D'EugenioAnna de GraaffHannah ÜblerSandro TacchellaEmma Curtis-LakeSantiago ArribasAndrew J BunkerStephane CharlotJacopo ChevallardMirko CurtiTobias J LooserMichael V MasedaTimothy D RawleBruno Rodríguez Del PinoChris J WillottEiichi EgamiDaniel J EisensteinKevin N HainlineBrant E RobertsonChristina C WilliamsChristopher N A WillmerWilliam M BakerKristan BoyettChrista DeCourseyAndrew C FabianJakob M HeltonZhiyuan JiGareth C JonesNimisha KumariNicolas LaporteErica J NelsonMichele PernaLester SandlesIrene ShivaeiFengwu Sun
Published in: Nature (2024)
Several theories have been proposed to describe the formation of black hole seeds in the early Universe and to explain the emergence of very massive black holes observed in the first thousand million years after the Big Bang 1-3 . Models consider different seeding and accretion scenarios 4-7 , which require the detection and characterization of black holes in the first few hundred million years after the Big Bang to be validated. Here we present an extensive analysis of the JWST-NIRSpec spectrum of GN-z11, an exceptionally luminous galaxy at z = 10.6, revealing the detection of the [NeIV]λ2423 and CII*λ1335 transitions (typical of active galactic nuclei), as well as semi-forbidden nebular lines tracing gas densities higher than 10 9  cm -3 , typical of the broad line region of active galactic nuclei. These spectral features indicate that GN-z11 hosts an accreting black hole. The spectrum also reveals a deep and blueshifted CIVλ1549 absorption trough, tracing an outflow with velocity 800-1,000 km s -1 , probably driven by the active galactic nucleus. Assuming local virial relations, we derive a black hole mass of log ( M BH / M ⊙ ) = 6.2 ± 0.3 , accreting at about five times the Eddington rate. These properties are consistent with both heavy seeds scenarios and scenarios considering intermediate and light seeds experiencing episodic super-Eddington phases. Our finding explains the high luminosity of GN-z11 and can also provide an explanation for its exceptionally high nitrogen abundance.
Keyphrases
  • climate change
  • perovskite solar cells
  • magnetic resonance imaging
  • big data
  • magnetic resonance
  • computed tomography
  • deep learning
  • label free
  • room temperature
  • ionic liquid
  • wastewater treatment
  • microbial community