Yellow supergiant star

A yellow supergiant star is a star, generally of spectral type F or G, having a supergiant luminosity class (e.g. Ia or Ib). They are stars that have evolved away from the main sequence, expanding and becoming more luminous.

Yellow supergiants are smaller than red supergiants; naked eye examples include Canopus and Polaris. Many of them are variable stars, mostly pulsating Cepheids such as δ Cephei itself.

HR-diag-no-text-2

Spectrum

Yellow supergiants generally have spectral types of F and G, although sometimes late A or early K stars are included.[1][2][3] These spectral types are characterised by hydrogen lines that are very strong in class A, weakening through F and G until they are very weak or absent in class K. Calcium H and K lines are present in late A spectra, but stronger in class F, and strongest in class G, before weakening again in cooler stars. Lines of ionised metals are strong in class A, weaker in class F and G, and absent from cooler stars. In class G, neutral metal lines are also found, along with CH molecular bands.[4]

Supergiants are identified in the Yerkes spectral classification by luminosities classes Ia and Ib, with intermediates such as Iab and Ia/ab sometimes being used. These luminosity classes are assigned using spectral lines that are sensitive to luminosity. Historically, the Ca H and K line strengths have been used for yellow stars, as well as the strengths of various metal lines.[5] The neutral oxygen lines, such as the 777.3 nm triplet, have also been used since they are extremely sensitive to luminosity across a wide range of spectral types.[6] Modern atmospheric models can accurately match all the spectral line strengths and profiles to give a spectral classification, or even skip straight to the physical parameters of the star, but in practice luminosity classes are still usually assigned by comparison against standard stars.[4]

Some yellow supergiant spectral standard stars:[7]

Properties

Ssc2006-03a
The massive RSGC1 cluster contains 14 red supergiants and one yellow supergiant.[8]

Yellow supergiants have a relatively narrow range of temperatures corresponding to their spectral types, from about 4,000 K to 7,000 K.[9] Their luminosities range from about 1,000 L upwards, with the most luminous stars exceeding 100,000 L. The high luminosities indicate that they are much larger than the sun, from about 30 R to several hundred R.[10]

The masses of yellow supergiants vary greatly, from less than the sun for stars such as W Virginis to 20 M or more (e.g. V810 Centauri). Corresponding surface gravities (log(g) cgs) are around 1–2 for high-mass supergiants, but can be as low as 0 for low-mass supergiants.[9][11]

Yellow supergiants are rare stars, much less common than red supergiants and main sequence stars. In M31 (Andromeda Galaxy), 16 yellow supergiants are seen associated with evolution from class O stars, of which there are around 25,000 visible.[12]

Variability

Delta Cephei lightcurve
Light curve of Delta Cephei, a yellow supergiant classical Cepheid variable

Many yellow supergiants are in a region of the HR diagram known as the instability strip because their temperatures and luminosities cause them to be dynamically unstable. Most yellow supergiants observed in the instability strip are Cepheid variables, named for δ Cephei, which pulsate with well-defined periods that are related to their luminosities. This means they can be used as standard candles for determining the distance of stars knowing only their period of variability. Cepheids with longer periods are cooler and more luminous.[13]

Two distinct types of Cepheid variable have been identified, which have different period-luminosity relationships: Classical Cepheid variables are young massive population I stars; type II Cepheids are older population II stars with low masses, including W Virginis variables, BL Herculis variables and RV Tauri variables. The Classical Cepheids are more luminous than the type II Cepheids with the same period.[14]

R Coronae Borealis variables are often yellow supergiants, but their variability is produced by a different mechanism from the Cepheids. At irregular intervals, they become obscured by dust condensation around the star and their brightness drops dramatically.[15]

Evolution

Evolutionary track 5m
Evolution of a 5 M star, showing a blue loop and post-AGB track across the yellow supergiant region

Supergiants are stars that have evolved away from the main sequence after exhausting the hydrogen in their cores. Yellow supergiants are a heterogenous group of stars crossing the standard categories of stars in the HR diagram at various different stages of their evolution.

Stars more massive than 8–12 M spend a few million years on the main sequence as class O and early B stars until the dense hydrogen in their cores becomes depleted. Then they expand and cool to become supergiants. They spend a few thousand years as a yellow supergiant while cooling, then spend one to four million years as a red supergiant, typically. Supergiants make up less than 1% of stars; though different proportions in the visible early eras of the universe. The relatively brief phases and concentration of matter explains the rarity of these stars.[16]

Some red supergiants undergo a blue loop, temporarily re-heating and becoming yellow or even blue supergiants before cooling again. Stellar models show that blue loops rely on particular chemical makeups and other assumptions, but they are most likely for stars of low red supergiant mass. While cooling for the first time or when performing a sufficiently extended blue loop, yellow supergiants will cross the instability strip and pulsate as Classical Cepheid variables with periods around ten days and longer.[17][18]

Intermediate mass stars leave the main sequence by cooling along the subgiant branch until they reach the red giant branch. Stars more massive than about 2 M have a sufficiently large helium core that it begins fusion before becoming degenerate. These stars will perform a blue loop.

For masses between about 5 M and 12 M, the blue loop can extend to F and G spectral types at luminosities reaching 1,000 L. These stars may develop supergiant luminosity classes, especially if they are pulsating. When these stars cross the instability strip they will pulsate as short period Cepheids. Blue loops in these stars can last for around 10 million years, so this type of yellow supergiant is more common than the more luminous types.[19][20]

Stars with masses similar to the sun develop degenerate helium cores after they leave the main sequence and ascend to the tip of the red giant branch where they ignite helium in a flash. They then fuse core helium on the horizontal branch with luminosities too low to be considered supergiants.

Stars leaving the blue half of the horizontal branch to be classified in the asymptotic giant branch (AGB) pass through the yellow classifications and will pulsate as BL Herculis variables. Such yellow stars may be given a supergiant luminosity class despite their low masses but assisted by luminous pulsation. In the AGB thermal pulses from the helium-fusing shell of stars may cause a blue loop across the instability strip. Such stars will pulsate as W Virginis variables and again may be classified as relatively low luminosity yellow supergiants.[14] When the hydrogen-fusing shell of a low or intermediate mass star of the AGB nears its surface, the cool outer layers are rapidly lost, which causes the star to heat up, eventually becoming a white dwarf. These stars have masses lower than the sun, but luminosities that can be 10,000 L or higher, so they will become yellow supergiants for a short time. Post-AGB stars are believed to pulsate as RV Tauri variables when they cross the instability strip.[21]

The evolutionary status of yellow supergiant R Coronae Borealis variables is unclear. They may be post-AGB stars reignited by a late helium shell flash, or they could be formed from white dwarf mergers.[22]

It is expected that first-time yellow supergiants mature to the red supergiant stage without any supernova. The cores of some post-red supergiant yellow supergiants might collapse and trigger a supernova. A handful of supernovae have been associated with apparent yellow supergiant progenitors that are not luminous enough to be post-red supergiants. If these are confirmed then an explanation must be found for how a star of moderate mass still with a helium core would cause a core-collapse supernova. The obvious candidate in such cases is always some form of binary interaction.[23]

Yellow hypergiants

Particularly luminous and unstable yellow supergiants are often grouped into a separate class of stars called the yellow hypergiants. These are mostly thought to be post-red supergiant stars, very massive stars that have lost a considerable portion of their outer layers and are now evolving towards becoming blue supergiants and Wolf-Rayet stars.[24]

References

  1. ^ Chiosi, Cesare; Maeder, André (1986). "The Evolution of Massive Stars with Mass Loss". Annual Review of Astronomy and Astrophysics. 24: 329. Bibcode:1986ARA&A..24..329C. doi:10.1146/annurev.aa.24.090186.001553.
  2. ^ Giridhar, S.; Ferro, A.; Parrao, L. (1997). "Elemental Abundances and Atmospheric Parameters of Seven F-G Supergiants". Publications of the Astronomical Society of the Pacific. 109: 1077. Bibcode:1997PASP..109.1077G. doi:10.1086/133978.
  3. ^ Drout, Maria R.; Massey, Philip; Meynet, Georges (2012). "The Yellow and Red Supergiants of M33". The Astrophysical Journal. 750 (2): 97. arXiv:1203.0247. Bibcode:2012ApJ...750...97D. doi:10.1088/0004-637X/750/2/97.
  4. ^ a b Gray, Richard O.; Corbally, Christopher (2009). Stellar Spectral Classification. Stellar Spectral Classification by Richard O. Gray and Christopher J. Corbally. Princeton University Press. Bibcode:2009ssc..book.....G.
  5. ^ Morgan, William Wilson; Keenan, Philip Childs; Kellman, Edith (1943). "An atlas of stellar spectra, with an outline of spectral classification". Chicago. Bibcode:1943assw.book.....M.
  6. ^ Faraggiana, R.; Gerbaldi, M.; Van't Veer, C.; Floquet, M. (1988). "Behaviour of O I triplet Lambda-7773". Astronomy and Astrophysics. 201: 259. Bibcode:1988A&A...201..259F.
  7. ^ Garcia, B. (1989). "A list of MK standard stars". Bulletin d'Information du Centre de Donnees Stellaires. 36: 27. Bibcode:1989BICDS..36...27G.
  8. ^ Figer, Donald F.; MacKenty, John W.; Robberto, Massimo; Smith, Kester; Najarro, Francisco; Kudritzki, Rolf P.; Herrero, Artemio (2006). "Discovery of an Extraordinarily Massive Cluster of Red Supergiants". The Astrophysical Journal. 643 (2): 1166. arXiv:astro-ph/0602146. Bibcode:2006ApJ...643.1166F. doi:10.1086/503275.
  9. ^ a b Parsons, S. B. (1971). "Effective temperatures, intrinsic colours, and surface gravities of yellow supergiants and cepheids". Monthly Notices of the Royal Astronomical Society. 152: 121. Bibcode:1971MNRAS.152..121P. doi:10.1093/mnras/152.1.121.
  10. ^ Burki, G. (1978). "The semi-period-luminosity-color relation for supergiant stars". Astronomy and Astrophysics. 65: 357. Bibcode:1978A&A....65..357B.
  11. ^ Gonzalez, Guillermo; Lambert, David L.; Giridhar, Sunetra (1997). "Abundance Analyses of the Field RV Tauri Variables: EP Lyrae, DY Orionis, AR Puppis, and R Sagittae". The Astrophysical Journal. 479: 427. Bibcode:1997ApJ...479..427G. doi:10.1086/303852.
  12. ^ Drout, Maria R.; Massey, Philip; Meynet, Georges; Tokarz, Susan; Caldwell, Nelson (2009). "Yellow Supergiants in the Andromeda Galaxy (M31)". The Astrophysical Journal. 703: 441. arXiv:0907.5471. Bibcode:2009ApJ...703..441D. doi:10.1088/0004-637X/703/1/441.
  13. ^ Majaess, D. J.; Turner, D. G.; Lane, D. J. (2009). "Characteristics of the Galaxy according to Cepheids". Monthly Notices of the Royal Astronomical Society. 398: 263. arXiv:0903.4206. Bibcode:2009MNRAS.398..263M. doi:10.1111/j.1365-2966.2009.15096.x.
  14. ^ a b Wallerstein, G.; Cox, A. N. (1984). "The Population II Cepheids". Astronomical Society of the Pacific. 96: 677. Bibcode:1984PASP...96..677W. doi:10.1086/131406.
  15. ^ Asplund, M.; Gustafsson, B.; Lambert, D. L.; Rao, N. K. (2000). "The R Coronae Borealis stars – atmospheres and abundances". Astronomy and Astrophysics. 353: 287. Bibcode:2000A&A...353..287A.
  16. ^ Meynet, G.; Maeder, A. (2000). "Stellar evolution with rotation. V. Changes in all the outputs of massive star models". Astronomy and Astrophysics. 361: 101. arXiv:astro-ph/0006404. Bibcode:2000A&A...361..101M.
  17. ^ Meynet, Georges; Georgy, Cyril; Hirschi, Raphael; Maeder, André; Massey, Phil; Przybilla, Norbert; Nieva, M.-Fernanda (2011). "Red Supergiants, Luminous Blue Variables and Wolf-Rayet stars: The single massive star perspective". Société Royale des Sciences de Liège. 80: 266. arXiv:1101.5873. Bibcode:2011BSRSL..80..266M.
  18. ^ Meynet, Georges; Ekstrom, Sylvia; Maeder, André; Eggenberger, Patrick; Saio, Hideyuki; Chomienne, Vincent; Haemmerlé, Lionel (2013). "Models of Rotating Massive Stars: Impacts of Various Prescriptions". Studying Stellar Rotation and Convection. Studying Stellar Rotation and Convection. Lecture Notes in Physics. 865. p. 3. arXiv:1301.2487v1. Bibcode:2013LNP...865....3M. doi:10.1007/978-3-642-33380-4_1. ISBN 978-3-642-33379-8.
  19. ^ Pols, Onno R.; Schröder, Klaus-Peter; Hurley, Jarrod R.; Tout, Christopher A.; Eggleton, Peter P. (1998). "Stellar evolution models for Z = 0.0001 to 0.03". Monthly Notices of the Royal Astronomical Society. 298 (2): 525. Bibcode:1998MNRAS.298..525P. doi:10.1046/j.1365-8711.1998.01658.x.
  20. ^ Girardi, L.; Bressan, A.; Bertelli, G.; Chiosi, C. (2000). "Evolutionary tracks and isochrones for low- and intermediate-mass stars: From 0.15 to 7 Msun, and from Z=0.0004 to 0.03". Astronomy and Astrophysics Supplement. 141 (3): 371. arXiv:astro-ph/9910164. Bibcode:2000A&AS..141..371G. doi:10.1051/aas:2000126.
  21. ^ Van Winckel, Hans (2003). "Post-AGB Stars". Annual Review of Astronomy and Astrophysics. 41: 391. Bibcode:2003ARA&A..41..391V. doi:10.1146/annurev.astro.41.071601.170018.
  22. ^ Clayton, Geoffrey C.; Geballe, T. R.; Herwig, Falk; Fryer, Christopher; Asplund, Martin (2007). "Very Large Excesses of 18O in Hydrogen-deficient Carbon and R Coronae Borealis Stars: Evidence for White Dwarf Mergers". The Astrophysical Journal. 662 (2): 1220. arXiv:astro-ph/0703453. Bibcode:2007ApJ...662.1220C. doi:10.1086/518307.
  23. ^ Bersten, M. C.; Benvenuto, O. G.; Nomoto, K. I.; Ergon, M.; Folatelli, G. N.; Sollerman, J.; Benetti, S.; Botticella, M. T.; Fraser, M.; Kotak, R.; Maeda, K.; Ochner, P.; Tomasella, L. (2012). "The Type IIb Supernova 2011dh from a Supergiant Progenitor". The Astrophysical Journal. 757: 31. arXiv:1207.5975. Bibcode:2012ApJ...757...31B. doi:10.1088/0004-637X/757/1/31.
  24. ^ Stothers, R. B.; Chin, C. W. (2001). "Yellow Hypergiants as Dynamically Unstable Post–Red Supergiant Stars". The Astrophysical Journal. 560 (2): 934. Bibcode:2001ApJ...560..934S. doi:10.1086/322438.
HD 102839

HD 102839 is a class G6Ib (yellow supergiant) star in the constellation Musca. Its apparent magnitude is 4.98 and it is approximately 950 light years away from Earth based on parallax.

HD 179821

HD 179821 is a yellow supergiant star in the constellation of Aquila, surrounded by a detached dust shell. It is a semi-regular variable and either a moderate-mass post-AGB star or distant massive yellow hypergiant among the largest known stars.

HD 59890

HD 59890 is a class G3Ib (yellow supergiant) star in the constellation Puppis. Its apparent magnitude is 4.65 and it is approximately 1500 light years away based on parallax.

R Coronae Borealis

R Coronae Borealis is a peculiar low-mass yellow supergiant star in the constellation of Corona Borealis. It is the prototype of the rare RCB class of variable stars, which fade by several magnitudes at irregular intervals. R Coronae Borealis itself normally shines at approximately magnitude 6, just about visible to the naked eye, but at intervals of several months to many years fades to as faint as 15th magnitude. Over successive months it then gradually returns to its normal brightness, giving it the nickname "reverse nova".

Supergiant (disambiguation)

A supergiant is a massive and luminous star, including:

Blue supergiant star, a hot supergiant

Yellow supergiant star, a supergiant with a temperature similar to the sun

Red supergiant star, a cool supergiantSupergiant may also refer to:

Supergiant Games, a video game development company

Super Giant, a Japanese superhero

Alicella gigantea, the supergiant Amphipod

Rising Pune Supergiant, a cricket team in the Indian Premier League

Type-cD galaxy, a supergiant elliptical galaxy

Supergiant, a fictional character in the Marvel Universe

W Mensae

W Mensae (W Men) is an unusual yellow supergiant star in the Large Magellanic Cloud in the southern constellation Mensa. It is an R Coronae Borealis variable and periodically decreases in brightness by several magnitudes.

W Men is very distant, being located in the neighboring galaxy Large Magellanic Cloud, where it lies on the southern metal-deficient edge. Despite its high luminosity, the star has a maximum apparent brightness of +13.8m, too dim to be visible in a small telescope. Its radius has been calculated to be 61 times that of the Sun.The variability of W Men was discovered in 1927 by W. J. Luyten. It belongs to the very rare R Coronae Borealis class of variables which are often called "inverse novae" since they experience occasional very large drops in brightness. At minimum brightness, W Men has a photographic (blue) magnitude less than +18.3, being undetectable on photographic plates at the time. The drop in brightness is less pronounced at longer wavelengths, and the overall luminosity of the star is thought to be largely unchanged. The variations are caused by condensation of dust which temporarily obscures the star. Short wavelengths of light are absorbed and re-emitted as infra-red. Many R CrB variables show small amplitude pulsations and W Mensae has a pulsation period of approximately 67 days.

Formation
Evolution
Luminosity class
Spectral
classification
Remnants
Hypothetical
stars
Nucleosynthesis
Structure
Properties
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