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Stellar collision

From Wikipedia, the free encyclopedia
Simulated collision of two neutron stars

A stellar collision is the coming together of two stars[1] caused by stellar dynamics within a star cluster, or by the orbital decay of a binary star due to stellar mass loss or gravitational radiation, or by other mechanisms not yet well understood.

Any stars in the universe can collide, whether they are "alive", meaning fusion is still active in the star, or "dead", with fusion no longer taking place. White dwarf stars, neutron stars, black holes, main sequence stars, giant stars, and supergiants are very different in type, mass, temperature, and radius, and accordingly produce different types of collisions and remnants.[2]

Types of stellar collisions and mergers

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Binary star mergers

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About half of all the stars in the sky are part of binary systems, with two stars orbiting each other. Some binary stars orbit each other so closely that they share the same atmosphere, giving the system a peanut shape. While most such contact binary systems are stable, some do become unstable and either eject one partner or eventually merge.

Astronomers predict that events of this type occur in the globular clusters of our galaxy about once every 10,000 years.[2] On 2 September 2008 scientists first observed a stellar merger in Scorpius (named V1309 Scorpii), though it was not known to be the result of a stellar merger at the time.[3]

Type Ia supernovae

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White dwarfs are the remnants of low-mass stars which, if they form a binary system with another star, can cause large stellar explosions known as type Ia supernovae. The normal route by which this happens involves a white dwarf drawing material off a main sequence or red giant star to form an accretion disc.

Much more rarely, a type Ia supernova occurs when two white dwarfs orbit each other closely.[4] Emission of gravitational waves causes the pair to spiral inward. When they finally merge, if their combined mass approaches or exceeds the Chandrasekhar limit, carbon fusion is ignited, raising the temperature. Since a white dwarf consists of degenerate matter, there is no safe equilibrium between thermal pressure and the weight of overlying layers of the star. Because of this, runaway fusion reactions rapidly heat up the interior of the combined star and spread, causing a supernova explosion.[4] In a matter of seconds, all of the white dwarf's mass is thrown into space.[5]

Neutron star mergers

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Neutron star mergers occur in a fashion similar to the rare type Ia supernovae resulting from merging white dwarfs. When two neutron stars orbit each other closely, they spiral inward as time passes due to gravitational radiation. When they meet, their merger leads to the formation of either a heavier neutron star or a black hole, depending on whether the mass of the remnant exceeds the Tolman–Oppenheimer–Volkoff limit. This creates a magnetic field that is trillions of times stronger than that of Earth, in a matter of one or two milliseconds. Astronomers believe that this type of event is what creates short gamma-ray bursts[6] and kilonovae.[7]

A gravitational wave event that occurred on 25 August 2017, GW170817, was reported on 16 October 2017 to be associated with the merger of two neutron stars in a distant galaxy, the first such merger to be observed via gravitational radiation.[8][9][10][11]

Thorne–Żytkow objects

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If a neutron star collides with red giant of sufficiently low mass and density, the merger is conjectured to produce a Thorne–Żytkow object, an hypothetical type of compact star containing a neutron star enveloped by a red giant.

Formation of planets

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When two low-mass stars in a binary system merge, mass may be thrown off in the orbital plane of the merging stars, creating an excretion disk from which new planets can form.[12]

Discovery

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While the concept of stellar collision has been around for several generations of astronomers, only the development of new technology has made it possible for it to be more objectively studied. For example, in 1764, a cluster of stars known as Messier 30 was discovered by astronomer Charles Messier. In the twentieth century, astronomers concluded that the cluster was approximately 13 billion years old.[13] The Hubble Space Telescope resolved the individual stars of Messier 30. With this new technology, astronomers discovered that some stars, known as blue stragglers, appeared younger than other stars in the cluster.[13] Astronomers then hypothesized that stars may have "collided", or "merged", giving them more fuel so they continued fusion while fellow stars around them started going out.[13]

Stellar collisions and the Solar System

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While stellar collisions may occur very frequently in certain parts of the galaxy, the likelihood of a collision involving the Sun is very small. A probability calculation predicts the rate of stellar collisions involving the Sun is 1 in 1028 years.[14] For comparison, the age of the universe is of the order 1010 years. The likelihood of close encounters with the Sun is also small. The rate is estimated by the formula:

N ≈ 4.2 · D2 Myr−1

where N is the number of encounters per million years that come within a radius D of the Sun in parsecs.[15] For comparison, the mean radius of the Earth's orbit, 1 AU, is 4.82 × 10−6 parsecs.

Our star will likely not be directly affected by such an event because there are no stellar clusters close enough to cause such interactions.[14]

KIC 9832227 and binary star mergers

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An analysis of the eclipses of KIC 9832227 initially suggested that its orbital period was indeed shortening, and that the cores of the two stars would merge in 2022.[16] [17][18] [19] However subsequent reanalysis found that one of the datasets used in the initial prediction contained a 12-hour timing error, leading to a spurious apparent shortening of the stars' orbital period.[20][21][22][23]

The mechanism behind binary star mergers is not yet fully understood, and remains one of the main focuses of those researching KIC 9832227 and other contact binaries.

References

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  1. ^ Fred Lawrence Whipple (March 1939), "Supernovae and stellar collisions", Proceedings of the National Academy of Sciences of the United States of America, 25 (3): 118–25, Bibcode:1939PNAS...25..118W, doi:10.1073/pnas.25.3.118, PMC 1077725, PMID 16577876
  2. ^ a b Chang, Kenneth (13 June 2000), "Two Stars Collide; New Star is Born", The New York Times, retrieved 14 November 2010
  3. ^ Tylenda, R.; Hajduk, M.; Kamiński, T.; et al. (11 April 2011). "V1309 Scorpii: merger of a contact binary". Astronomy and Astrophysics. 528: A114. arXiv:1012.0163. Bibcode:2011A&A...528A.114T. doi:10.1051/0004-6361/201016221. S2CID 119234303.
  4. ^ a b González Hernández, J. I.; Ruiz-Lapuente, P.; Tabernero, H. M.; Montes, D.; Canal, R.; Méndez, J.; Bedin, L. R. (26 September 2012). "No surviving evolved companions of the progenitor of SN 1006". Nature. 489 (7417): 533–536. arXiv:1210.1948. Bibcode:2012Natur.489..533G. doi:10.1038/nature11447. hdl:2445/127740. PMID 23018963. S2CID 4431391.
  5. ^ Freedman, Roger A., Robert M. Geller, William J. Kaufmann III(2009). The Universe 9th Edition,p.543-545. W.H. Freeman and Company, New York. ISBN 1-4292-3153-X
  6. ^ Rosswog, Stephan (2013). "Astrophysics: Radioactive glow as a smoking gun". Nature. 500 (7464): 535–6. Bibcode:2013Natur.500..535R. doi:10.1038/500535a. PMID 23985867.
  7. ^ Metzger, B. D.; Martínez-Pinedo, G.; Darbha, S.; Quataert, E.; et al. (August 2010). "Electromagnetic counterparts of compact object mergers powered by the radioactive decay of r-process nuclei". Monthly Notices of the Royal Astronomical Society. 406 (4): 2650. arXiv:1001.5029. Bibcode:2010MNRAS.406.2650M. doi:10.1111/j.1365-2966.2010.16864.x. S2CID 118863104.
  8. ^ Overbye, Dennis (16 October 2017), "LIGO Detects Fierce Collision of Neutron Stars for the First Time", The New York Times
  9. ^ Casttelvecchi, Davide (25 August 2017). "Rumours swell over new kind of gravitational-wave sighting". Nature. doi:10.1038/nature.2017.22482. Retrieved 27 August 2017.
  10. ^ Sokol, Josha (25 August 2017). "What Happens When Two Neutron Stars Collide?". Wired. Retrieved 27 August 2017.
  11. ^ Drake, Nadia (25 August 2017). "Strange Stars Caught Wrinkling Spacetime? Get the Facts". National Geographic. Archived from the original on August 27, 2017. Retrieved 27 August 2017.
  12. ^ Martin, E. L.; Spruit, H. C.; Tata, R. (2011). "A binary merger origin for inflated hot Jupiter planets". Astronomy & Astrophysics. 535: A50. arXiv:1102.3336. Bibcode:2011A&A...535A..50M. doi:10.1051/0004-6361/201116907. S2CID 118473108.
  13. ^ a b c "Stellar Collisions and vampirism give blue stragglers stars a 'cosmic facelift'", Asian News International, 29 December 2009
  14. ^ a b Lucentini, Jack (1 June 2000). "Researchers Claim First Proof That Stars Collide". Space.com. Archived from the original on 19 April 2004. Retrieved 15 January 2014. By one calculation, the sun is likely to have one crash per 10,000 trillion, trillion years (that's 28 zeros), and it will burn out on its own accord much sooner than that.
  15. ^ Garcia-Sanchez, J.; et al. (24 August 1998), "Perturbation of the Oort Cloud by Close Stellar Approaches", Asteroid and Comet Dynamics, Tatrauska Lomnica, Slovak Republic, hdl:2014/19368{{citation}}: CS1 maint: location missing publisher (link)
  16. ^ Molnar, Lawrence A.; Noord, Daniel M. Van; Kinemuchi, Karen; Smolinski, Jason P.; Alexander, Cara E.; Cook, Evan M.; Jang, Byoungchan; Kobulnicky, Henry A.; Spedden, Christopher J. (2017). "Prediction of a Red Nova Outburst in KIC 9832227". The Astrophysical Journal. 840 (1): 1. arXiv:1704.05502. Bibcode:2017ApJ...840....1M. doi:10.3847/1538-4357/aa6ba7. ISSN 0004-637X. S2CID 118970956.
  17. ^ Kinemuchi, Karen (1 October 2013). "To Pulsate or to Eclipse? Status of KIC 9832227 Variable Star". arXiv:1310.0544 [astro-ph.SR].
  18. ^ Byrd, Deborah (6 January 2017). "Star predicted to explode in 2022". EarthSky. EarthSky Communications. Retrieved 6 January 2017.
  19. ^ "Colliding stars will light up the night sky in 2022". Science. 1 May 2017. Retrieved 7 January 2017.
  20. ^ Molnar, Lawrence A. (7 September 2018). "Supplementary material to Calvin College press release "Team of researchers challenge bold astronomical prediction", September 7, 2018". calvin.edu. Retrieved 8 September 2018.
  21. ^ Kucinski, Matt (7 September 2018). "Team of researchers challenge bold astronomical prediction". calvin.edu. Retrieved 8 September 2018.
  22. ^ Socia, Quentin J.; Welsh, William F.; Short, Donald R.; Orosz, Jerome A.; Angione, Ronald J.; Windmiller, Gur; Caldwell, Douglas A.; Batalha, Natalie M. (11 September 2018). "KIC 9832227: Using Vulcan Data to Negate the 2022 Red Nova Merger Prediction". Astrophysical Journal Letters. 864 (2): L32. arXiv:1809.02771. Bibcode:2018ApJ...864L..32S. doi:10.3847/2041-8213/aadc0d. S2CID 56134618.
  23. ^ Parks, Jake (7 September 2018). "Two stars will NOT merge and explode into red fury in 2022". astronomy.com.
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