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Altair

Coordinates: Sky map 19h 50m 46.9990s, +08° 52′ 05.959″
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Altair
Location of Altair (circled)
Observation data
Epoch J2000.097      Equinox J2000.0 (ICRS)
Constellation Aquila
Pronunciation /ˈæltɛər/, /ˈæltaɪər/[1][2]
Right ascension 19h 50m 46.99855s[3]
Declination +08° 52′ 05.9563″[3]
Apparent magnitude (V) 0.76[4]
Characteristics
Evolutionary stage Main sequence
Spectral type A7Vn[5]
U−B color index +0.09[4]
B−V color index +0.22[4]
V−R color index +0.14[4]
R−I color index +0.13[4]
Variable type Delta Scuti[6]
Astrometry
Radial velocity (Rv)−26.1±0.9[7] km/s
Proper motion (μ) RA: +536.23[3] mas/yr
Dec.: +385.29[3] mas/yr
Parallax (π)194.95 ± 0.57 mas[3]
Distance16.73 ± 0.05 ly
(5.13 ± 0.01 pc)
Absolute magnitude (MV)2.22[6]
Details
Mass1.86±0.03[8] M
Radius1.57 – 2.01[8][nb 1] R
Luminosity10.6[9] L
Surface gravity (log g)4.29[10] cgs
Temperature6,860 – 8,621[8][nb 1] K
Metallicity [Fe/H]−0.2[11] dex
Rotation7.77 hours[9]
Rotational velocity (v sin i)242[8] km/s
Age100[8] Myr
Other designations
Atair, α Aquilae, α Aql, Alpha Aquilae, Alpha Aql, 53 Aquilae, 53 Aql, BD+08°4236, FK5 745, GJ 768, HD 187642, HIP 97649, HR 7557, SAO 125122, WDS 19508+0852A, LFT 1499, LHS 3490, LTT 15795, NLTT 48314[7][12][13]
Database references
SIMBADdata

Altair is the brightest star in the constellation of Aquila and the twelfth-brightest star in the night sky. It has the Bayer designation Alpha Aquilae, which is Latinised from α Aquilae and abbreviated Alpha Aql or α Aql. Altair is an A-type main-sequence star with an apparent visual magnitude of 0.77 and is one of the vertices of the Summer Triangle asterism; the other two vertices are marked by Deneb and Vega.[7][14][15] It is located at a distance of 16.7 light-years (5.1 parsecs) from the Sun.[16]: 194  Altair is currently in the G-cloud—a nearby interstellar cloud, an accumulation of gas and dust.[17][18]

Altair rotates rapidly, with a velocity at the equator of approximately 286 km/s.[nb 2][11] This is a significant fraction of the star's estimated breakup speed of 400 km/s.[19] A study with the Palomar Testbed Interferometer revealed that Altair is not spherical, but is flattened at the poles due to its high rate of rotation.[20] Other interferometric studies with multiple telescopes, operating in the infrared, have imaged and confirmed this phenomenon.[11]

Nomenclature

[edit]
Altair is the brightest star in the constellation Aquila.

α Aquilae (Latinised to Alpha Aquilae) is the star's Bayer designation. The traditional name Altair has been used since medieval times. It is an abbreviation of the Arabic phrase النسر الطائر Al-Nisr Al-Ṭa'ir, "the flying eagle".[21]

In 2016, the International Astronomical Union organized a Working Group on Star Names (WGSN)[22] to catalog and standardize proper names for stars. The WGSN's first bulletin of July 2016[23] included a table of the first two batches of names approved by the WGSN, which included Altair for this star. It is now so entered in the IAU Catalog of Star Names.[24]

Physical characteristics

[edit]
Altair in comparison with the Sun

Along with β Aquilae and γ Aquilae, Altair forms the well-known line of stars sometimes referred to as the Family of Aquila or Shaft of Aquila.[16]: 190 

Altair is a type-A main-sequence star with about 1.8 times the mass of the Sun and 11 times its luminosity.[11][9] It is thought to be a young star close to the zero age main sequence at about 100 million years old, although previous estimates gave an age closer to one billion years old.[8] Altair rotates rapidly, with a rotational period of under eight hours;[8] for comparison, the equator of the Sun makes a complete rotation in a little more than 25 days, but Altair's rotation is similar to, and slightly faster than, those of Jupiter and Saturn. Like those two planets, its rapid rotation causes the star to be oblate; its equatorial diameter is over 20 percent greater than its polar diameter.[11]

A light curve for Altair, adapted from Buzasi et al. (2005)[6]

Satellite measurements made in 1999 with the Wide Field Infrared Explorer showed that the brightness of Altair fluctuates slightly, varying by just a few thousandths of a magnitude with several different periods less than 2 hours.[6] As a result, it was identified in 2005 as a Delta Scuti variable star. Its light curve can be approximated by adding together a number of sine waves, with periods that range between 0.8 and 1.5 hours.[6] It is a weak source of coronal X-ray emission, with the most active sources of emission being located near the star's equator. This activity may be due to convection cells forming at the cooler equator.[19]

Rotational effects

[edit]
Direct image of Altair, taken with the CHARA array

The angular diameter of Altair was measured interferometrically by R. Hanbury Brown and his co-workers at Narrabri Observatory in the 1960s. They found a diameter of 3 milliarcseconds.[25] Although Hanbury Brown et al. realized that Altair would be rotationally flattened, they had insufficient data to experimentally observe its oblateness. Later, using infrared interferometric measurements made by the Palomar Testbed Interferometer in 1999 and 2000, Altair was found to be flattened. This work was published by G. T. van Belle, David R. Ciardi and their co-authors in 2001.[20]

Theory predicts that, owing to Altair's rapid rotation, its surface gravity and effective temperature should be lower at the equator, making the equator less luminous than the poles. This phenomenon, known as gravity darkening or the von Zeipel effect, was confirmed for Altair by measurements made by the Navy Precision Optical Interferometer in 2001, and analyzed by Ohishi et al. (2004) and Peterson et al. (2006).[9][26] Also, A. Domiciano de Souza et al. (2005) verified gravity darkening using the measurements made by the Palomar and Navy interferometers, together with new measurements made by the VINCI instrument at the VLTI.[27]

Altair is one of the few stars for which a direct image has been obtained.[28] In 2006 and 2007, J. D. Monnier and his coworkers produced an image of Altair's surface from 2006 infrared observations made with the MIRC instrument on the CHARA array interferometer; this was the first time the surface of any main-sequence star, apart from the Sun, had been imaged.[28] The false-color image was published in 2007. The equatorial radius of the star was estimated to be 2.03 solar radii, and the polar radius 1.63 solar radii—a 25% increase of the stellar radius from pole to equator.[11] The polar axis is inclined by about 60° to the line of sight from the Earth.[19]

Etymology, mythology and culture

[edit]
Altair

The term Al Nesr Al Tair appeared in Al Achsasi al Mouakket's catalogue, which was translated into Latin as Vultur Volans.[29] This name was applied by the Arabs to the asterism of Altair, β Aquilae and γ Aquilae and probably goes back to the ancient Babylonians and Sumerians, who called Altair "the eagle star".[2]: 17–18  The spelling Atair has also been used.[30] Medieval astrolabes of England and Western Europe depicted Altair and Vega as birds.[31]

The Koori people of Victoria also knew Altair as Bunjil, the wedge-tailed eagle, and β and γ Aquilae are his two wives the black swans. The people of the Murray River knew the star as Totyerguil.[32]: 4  The Murray River was formed when Totyerguil the hunter speared Otjout, a giant Murray cod, who, when wounded, churned a channel across southern Australia before entering the sky as the constellation Delphinus.[32]: 115 

In Chinese belief, the asterism consisting of Altair, β Aquilae and γ Aquilae is known as Hé Gǔ (河鼓; lit. "river drum").[30] The Chinese name for Altair is thus Hé Gǔ èr (河鼓二; lit. "river drum two", meaning the "second star of the drum at the river").[33] However, Altair is better known by its other names: Qiān Niú Xīng (牵牛星 / 牽牛星) or Niú Láng Xīng (牛郎星), translated as the cowherd star.[34][35] These names are an allusion to a love story, The Cowherd and the Weaver Girl, in which Niulang (represented by Altair) and his two children (represented by β Aquilae and γ Aquilae) are separated from respectively their wife and mother Zhinu (represented by Vega) by the Milky Way. They are only permitted to meet once a year, when magpies form a bridge to allow them to cross the Milky Way.[35][36]

The people of Micronesia called Altair Mai-lapa, meaning "big/old breadfruit", while the Māori people called this star Poutu-te-rangi, meaning "pillar of heaven".[37]

In Western astrology, the star was ill-omened, portending danger from reptiles.[30]

This star is one of the asterisms used by Bugis sailors for navigation, called bintoéng timoro, meaning "eastern star".[38]

A group of Japanese scientists sent a radio signal to Altair in 1983 with the hopes of contacting extraterrestrial life.[39]

NASA announced Altair as the name of the Lunar Surface Access Module (LSAM) on December 13, 2007.[40] The Russian-made Beriev Be-200 Altair seaplane is also named after the star.[41]

Visual companions

[edit]

The bright primary star has the multiple star designation WDS 19508+0852A and has several faint visual companion stars, WDS 19508+0852B, C, D, E, F and G.[13] All are much more distant than Altair and not physically associated.[42]

Multiple/double star designation: WDS 19508+0852[13]
Component Primary Right
ascension
(α)
Equinox J2000.0
Declination (δ)
Equinox J2000.0
Epoch of
observed
separation
Angular
distance
from
primary
Position
angle
(relative
to primary)
Apparent
magnitude
(V)
Database
reference
B A 19h 50m 40.5s+08° 52′ 13″[43] 2015 195.8 286° 9.8 SIMBAD
C A 19h 51m 00.8s+08° 50′ 58″[44] 2015 186.4 110° 10.3 SIMBAD
D A 2015 26.8 105° 11.9
E A 2015 157.3 354° 11.0
F A 19h 51m 02.0s+08° 55′ 33″ 2015 292.4 48° 10.3 SIMBAD
G A 2015 185.1 121° 13.0

See also

[edit]

Notes

[edit]
  1. ^ a b Owing to its rapid rotation, Altair's radius is larger at its equator than at its poles; it is also cooler at the equator than at the poles.
  2. ^ From values of v sin i and i in the second column of Table 1, Monnier et al. 2007.

References

[edit]
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  2. ^ a b Kunitzsch, Paul; Smart, Tim (2006). A Dictionary of Modern star Names: A Short Guide to 254 Star Names and Their Derivations (2nd rev. ed.). Cambridge, Massachusetts: Sky Pub. ISBN 978-1-931559-44-7.
  3. ^ a b c d e van Leeuwen, F. (November 2007), "Validation of the new Hipparcos reduction", Astronomy and Astrophysics, 474 (2): 653–664, arXiv:0708.1752, Bibcode:2007A&A...474..653V, doi:10.1051/0004-6361:20078357, S2CID 18759600
  4. ^ a b c d e Ducati, J. R. (2002). "VizieR Online Data Catalog: Catalogue of Stellar Photometry in Johnson's 11-color system". CDS/ADC Collection of Electronic Catalogues. 2237: 0. Bibcode:2002yCat.2237....0D.
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  6. ^ a b c d e Buzasi, D. L.; Bruntt, H.; Bedding, T. R.; Retter, A.; Kjeldsen, H.; Preston, H. L.; Mandeville, W. J.; Suarez, J. C.; Catanzarite, J. (February 2005). "Altair: The Brightest δ Scuti Star". The Astrophysical Journal. 619 (2): 1072–1076. arXiv:astro-ph/0405127. Bibcode:2005ApJ...619.1072B. doi:10.1086/426704. ISSN 0004-637X. S2CID 16524681.
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  8. ^ a b c d e f g Bouchaud, K.; Domiciano De Souza, A.; Rieutord, M.; Reese, D. R.; Kervella, P. (2020). "A realistic two-dimensional model of Altair". Astronomy and Astrophysics. 633: A78. arXiv:1912.03138. Bibcode:2020A&A...633A..78B. doi:10.1051/0004-6361/201936830. S2CID 208857428.
  9. ^ a b c d Peterson, D. M.; Hummel, C. A.; Pauls, T. A.; et al. (2006). "Resolving the Effects of Rotation in Altair with Long-Baseline Interferometry". The Astrophysical Journal. 636 (2): 1087–1097. arXiv:astro-ph/0509236. Bibcode:2006ApJ...636.1087P. doi:10.1086/497981. S2CID 18683397. See Table 2 for stellar parameters.
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  20. ^ a b Belle, Gerard T. van; Ciardi, David R.; Thompson, Robert R.; Akeson, Rachel L.; Lada, Elizabeth A. (2001). "Altair's Oblateness and Rotation Velocity from Long-Baseline Interferometry". The Astrophysical Journal. 559 (2): 1155–1164. Bibcode:2001ApJ...559.1155V. doi:10.1086/322340. ISSN 0004-637X. S2CID 13969695.
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  22. ^ "IAU Working Group on Star Names (WGSN)". Retrieved 22 May 2016.
  23. ^ "Bulletin of the IAU Working Group on Star Names, No. 1" (PDF). Archived (PDF) from the original on 2022-10-09. Retrieved 28 July 2016.
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  26. ^ Ohishi, Naoko; Nordgren, Tyler E.; Hutter, Donald J. (2004). "Asymmetric Surface Brightness Distribution of Altair Observed with the Navy Prototype Optical Interferometer". The Astrophysical Journal. 612 (1): 463–471. arXiv:astro-ph/0405301. Bibcode:2004ApJ...612..463O. doi:10.1086/422422. S2CID 15857535.
  27. ^ Domiciano de Souza, A.; Kervella, P.; Jankov, S.; Vakili, F.; Ohishi, N.; Nordgren, T. E.; Abe, L. (2005). "Gravitational-darkening of Altair from interferometry". Astronomy & Astrophysics. 442 (2): 567–578. Bibcode:2005A&A...442..567D. doi:10.1051/0004-6361:20042476.
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  30. ^ a b c Allen, Richard Hinckley (1899). Star-names and their meanings. unknown library. New York, Leipzig [etc.] G.E. Stechert. pp. 59–60.
  31. ^ Gingerich, O. (1987). "Zoomorphic Astrolabes and the Introduction of Arabic Star Names into Europe". Annals of the New York Academy of Sciences. 500 (1): 89–104. Bibcode:1987NYASA.500...89G. doi:10.1111/j.1749-6632.1987.tb37197.x. S2CID 84102853.
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  36. ^ pp. 105–107, Magic Lotus Lantern and Other Tales from the Han Chinese, Haiwang Yuan and Michael Ann Williams, Libraries Unlimited, 2006, ISBN 978-1-59158-294-6.
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  39. ^ "'Anybody there?' Astronomers waiting for a reply from Altair". August 20, 2023. Retrieved 2023-08-25.
  40. ^ "NASA names next-gen lunar lander Altair". .collectSPACE. December 13, 2007. Retrieved 2022-08-03.
  41. ^ "Results of the competition for the best personal names for the Be-103 and the Be-200 amphibious aircraft" (Press release). Beriev Aircraft Company. February 12, 2003. Archived from the original on 2021-11-05. Retrieved 2022-08-03.
  42. ^ Brown, A. G. A.; et al. (Gaia collaboration) (August 2018). "Gaia Data Release 2: Summary of the contents and survey properties". Astronomy & Astrophysics. 616. A1. arXiv:1804.09365. Bibcode:2018A&A...616A...1G. doi:10.1051/0004-6361/201833051.
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