Quasi-star explained
A quasi-star (also called black hole star) is a hypothetical type of extremely massive and luminous star that may have existed early in the history of the Universe. They are thought to live around 7-10 million years. Unlike modern stars, which are powered by nuclear fusion in their cores, a quasi-star's energy would come from material falling into a black hole at its core. They were first proposed in the 1960s and have since provided valuable insights into the early universe, galaxy formation, and the behavior of black holes. Although they have not been observed, they are considered to be a possible progenitor of supermassive black holes.[1]
Formation and properties
A quasi-star would have resulted from the core of a large protostar collapsing into a black hole, where the outer layers of the protostar are massive enough to absorb the resulting burst of energy without being blown away or falling into the black hole, as occurs with modern supernovae. Such a star would have to be at least 1000solar mass.[2] Quasi-stars may have also formed from dark matter halos drawing in enormous amounts of gas via gravity, which can produce supermassive stars with tens of thousands of solar masses.[3] [4] Formation of quasi-stars could only happen early in the development of the Universe before hydrogen and helium were contaminated by heavier elements; thus, they may have been very massive Population III stars.[5] Such stars would dwarf VY Canis Majoris, Mu Cephei and RSGC1-F01, four among the largest known modern stars.
Once the black hole had formed at the protostar's core, it would continue generating a large amount of radiant energy from the infall of stellar material. This constant outburst of energy would counteract the force of gravity, creating an equilibrium similar to the one that supports modern fusion-based stars.[6] Quasi-stars would have had a short maximum lifespan, approximately 7 million years,[7] during which the core black hole would have grown to about 1000solar mass10000solar mass.[1] [6] These intermediate-mass black holes have been suggested as the progenitors of modern supermassive black holes such as the one in the center of the Galaxy.
Quasi-stars are predicted to have had surface temperatures higher than 10000K.[6] At these temperatures, each one would be about as luminous as a small galaxy.[1] As a quasi-star cools over time, its outer envelope would become transparent, until further cooling to a limiting temperature of 4000K. This limiting temperature would mark the end of the quasi-star's life since there is no hydrostatic equilibrium at or below this limiting temperature. The object would then quickly dissipate, leaving behind the intermediate mass black hole.[6]
Further reading
- 10.1111/j.1365-2966.2011.18591.x . The structure and evolution of quasi-stars . 2011 . Ball . Warrick H. . Tout . Christopher A. . Żytkow . Anna N. . Eldridge . John J. . Monthly Notices of the Royal Astronomical Society . 414 . 3 . 2751–2762 . free . 1102.5098 . 2011MNRAS.414.2751B . 119239346 .
- 1207.5972 . Ball . Warrick H. . Quasi-stars and the Schönberg-Chandrasekhar limit . 2012 .
- 1207.1560 . 10.1088/2041-8205/755/1/L15 . Quasi-Star Jets as Unidentified Gamma-Ray Sources . 2012 . Czerny . Bozena . Janiuk . Agnieszka . Sikora . Marek . Lasota . Jean-Pierre . The Astrophysical Journal . 755 . 1 . L15 . 2012ApJ...755L..15C . 113397287 .
- 1604.03936 . 10.1093/mnras/stw2505 . Light or heavy supermassive black hole seeds: The role of internal rotation in the fate of supermassive stars . 2017 . Fiacconi . Davide . Rossi . Elena M. . Monthly Notices of the Royal Astronomical Society . 464 . 2 . 2259–2269 . free .
- 10.1093/mnras/stad572 . Modelling supermassive primordial stars with mesa . 2023 . Herrington . Nicholas P. . Whalen . Daniel J. . Woods . Tyrone E. . Monthly Notices of the Royal Astronomical Society . 521 . 463–473 . free . 2208.00008 .
- 1107.3562 . 10.1111/j.1365-2966.2011.19461.x . A lower limit on the halo mass to form supermassive black holes . 2011 . Dotan . Calanit . Rossi . Elena M. . Shaviv . Nir J. . Monthly Notices of the Royal Astronomical Society . 417 . 4 . 3035–3046 . free . 2011MNRAS.417.3035D .
External links
Notes and References
- News: Biggest black holes may grow inside 'quasistars'. 29 November 2007. NewScientist.com news service. Stephen. Battersby.
- 1102.5098 . 10.1111/j.1365-2966.2011.18591.x . The structure and evolution of quasi-stars . 2011 . Ball . Warrick H. . Tout . Christopher A. . Żytkow . Anna N. . Eldridge . John J. . Monthly Notices of the Royal Astronomical Society . 414 . 3 . 2751–2762 . free . 2011MNRAS.414.2751B .
- Web site: Zeroing In on How Supermassive Black Holes Formed. Yasemin Saplakoglu. Scientific American. September 29, 2017. April 8, 2019.
- Web site: Cooking up supermassive black holes in the early universe. Mara Johnson-Goh. Astronomy. November 20, 2017. April 8, 2019.
- Ball . Warrick H. . Tout . Christopher A. . Żytkow . Anna N. . Eldridge . John J. . 2011-07-01 . The structure and evolution of quasi-stars: The structure and evolution of quasi-stars . Monthly Notices of the Royal Astronomical Society . en . 414 . 3 . 2751–2762 . 10.1111/j.1365-2966.2011.18591.x. 2011MNRAS.414.2751B . free . 1102.5098 .
- Begelman. Mitch. Rossi, Elena . Armitage, Philip . Quasi-stars: accreting black holes inside massive envelopes. MNRAS. 2008. 387. 4. 1649–1659. 10.1111/j.1365-2966.2008.13344.x. free . 2008MNRAS.387.1649B. 0711.4078 . 12044015.
- 1305.5923. Massive black hole factories: Supermassive and quasi-star formation in primordial halos. Astronomy & Astrophysics. 558. A59. 25 May 2013. Schleicher. Dominik R. G.. Palla. Francesco. Ferrara. Andrea. Galli. Daniele. Latif. Muhammad. 10.1051/0004-6361/201321949. 2013A&A...558A..59S . 119197147.