UHZ1

In today's article, we are going to explore in detail about UHZ1, a topic that has captured the attention of millions of people around the world. UHZ1 is a topic that has generated a great debate in different areas and has aroused great interest in society. Throughout this article, we will analyze different aspects related to UHZ1, from its origins to its impact today. We will explore its different dimensions, its relevance today and the implications it has for different sectors. Additionally, we will examine the opinions of experts on the topic, as well as the experiences of people who have been directly affected by UHZ1. Without a doubt, this is a fascinating topic that deserves to be explored in depth. Join us on this fascinating journey of discovery about UHZ1!

UHZ1
Observation data (J2000 epoch)
ConstellationSculptor
Right ascension00h 14m 16.096s
Declination−30° 22′ 40.285″
Redshift10.1
Distance13.2 Gly (4.047 Gpc) (light travel distance)
31.7 Gly (9.719 Gpc) (comoving distance)
Characteristics
Size21,000 ly (in diameter)

UHZ1 is a background galaxy containing a quasar. At a redshift of approximately 10.1, UHZ1 is at a distance of 13.2 billion light-years, seen when our universe was about 3 percent of its current age.[1][2] This redshift made it the most distant, and therefore earliest known quasar in the observable universe as of 2023.[3][4] To detect this object, astronomers working at the Chandra X-ray Observatory used the Abell 2744's cluster mass as a gravitational lens in order to magnify distant objects directly behind it.[5] At the time of discovery, it exceeded the distance record of QSO J0313−1806.[6]

The discovery of this object has led astronomers to suggest the seeds of the first quasars may have been direct-collapse black holes, from the collapse of supermassive primordial stars at the beginning of our universe.[2]

Impact on astronomical research

The Chandra-JWST discovery of a quasar with a redshift of ≈ 10.1 at the center of UHZ1 reveals that accreting supermassive black holes (SMBHs) already existed at about 470 million years after the Big Bang.[7] The detection of early black holes as they transition from "seeds" to supermassive black holes (BHs) provides good sources at high redshift, facilitating the testing on seeding and growth models for BHs.[7][8][9] One of the open questions about the formation of supermassive BHs is whether they originate from stellar-mass black holes, remnants from the death of massive stars or whether there are mechanisms that operate to form heavier initial seeds to begin its formation. UHZ1's data shows it requires either continuous growth exceeding the Eddington limit for >200 Myr, or a massive seed. Data collected provides a clue to the seeding mechanism and supports it.[8]

UHZ1 as a potential first OBG candidate

The Chandra X-ray source detected in UHZ1 is Compton-thick.[a] It has a bolometric luminosity of Lbol ~ 5×1045 erg s×10−1, corresponding to an estimated BH mass of ~ 4×107 M⊙.[7][8][9]

The data collected from UHZ1 and its quasar are in agreement with prior theoretical predictions by astronomers for a unique class of transient, high-redshift objects known as Overmassive (or Outsize) Black Hole Galaxies (OBGs, or O.B.G.s). OBGs are heavy initial black hole seeds that likely formed from the direct collapse of gas clouds. Due to the agreement between the multi-wavelength properties of UHZ1 and the theoretical model template predictions, some astronomers suggest UHZ1 is the first detected OBG candidate.[7][8][9]

Footnotes

  1. ^ The quasar's X-ray emission comes from a hot atmosphere of gas called the corona, which surrounds the accretion disk. As X-ray photons leave the corona in high velocity, they might be absorbed by the surrounding torus of neutral hydrogen and dust surrounding the corona. If most of the X-ray photons are absorbed, the phenomenon is called "Compton-thick".

References

  1. ^ "APOD: 2023 November 10 - UHZ1: Distant Galaxy and Black Hole". apod.nasa.gov. Retrieved 2023-11-10.
  2. ^ a b Whalen, Daniel J.; Latif, Muhammad A.; Mezcua, Mar (2023-10-01). "Radio Emission From a z = 10.1 Black Hole in UHZ1". The Astrophysical Journal. 956 (2): 133. arXiv:2308.03837. Bibcode:2023ApJ...956..133W. doi:10.3847/1538-4357/acf92c. ISSN 0004-637X.
  3. ^ Bogdan; et al. (November 6, 2023), "Evidence for heavy-seed origin of early supermassive black holes from a z≈10 x-ray quasar", Nature Astronomy, 8: 126–133, arXiv:2305.15458, doi:10.1038/s41550-023-02111-9
  4. ^ Ashley Strickland (November 7, 2023). "Telescopes spot the oldest and most distant black hole formed after the big bang". CNN.
  5. ^ UHZ1 album, Chandra observatory, Smithsonian Inst., accessed 2023-11-07
  6. ^ Cosmin Ilie, Katherine Freese, Andreea Petric, Jillian Paulin (21 December 2023), UHZ1 and the other three most distant quasars observed: possible evidence for Supermassive Dark Stars, arXiv:2312.13837{{citation}}: CS1 maint: multiple names: authors list (link)
  7. ^ a b c d Natarajan, Priyamvada; Pacucci, Fabio; Ricarte, Angelo; Bogdan, Akos; Goulding, Andy D.; Cappelluti, Nico (2023-08-04). "First Detection of an Over-Massive Black Hole Galaxy UHZ1: Evidence for Heavy Black Hole Seed Formation from Direct Collapse". arXiv:2308.02654 .
  8. ^ a b c d Goulding, Andy D.; Greene, Jenny E.; Setton, David J.; Labbe, Ivo; Bezanson, Rachel; Miller, Tim B.; Atek, Hakim; Bogdán, Ákos; Brammer, Gabriel; Chemerynska, Iryna; Cutler, Sam E.; Dayal, Pratika; Fudamoto, Yoshinobu; Fujimoto, Seiji; Furtak, Lukas J. (2023-09-01). "UNCOVER: The Growth of the First Massive Black Holes from JWST/NIRSpec-Spectroscopic Redshift Confirmation of an X-Ray Luminous AGN at z = 10.1". The Astrophysical Journal. 955: L24. arXiv:2308.02750. Bibcode:2023ApJ...955L..24G. doi:10.3847/2041-8213/acf7c5. ISSN 0004-637X.
  9. ^ a b c Overbye, Dennis (24 December 2023). "How to Create a Black Hole Out of Thin Air - Black holes were thought to arise from the collapse of dead stars. But a Webb telescope image showing the early universe hints at an alternative pathway". The New York Times. Archived from the original on 25 December 2023. Retrieved 26 December 2023.
Records
Preceded by Most distant known quasar
2023 –  		Succeeded by