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Red-giant branch

February 15, 2024

The red-giant branch (RGB), sometimes called the first giant branch, is the portion of the giant branch before helium ignition occurs in the course of stellar evolution. It is a stage that follows the main sequence for low- to intermediate-mass stars. Red-giant-branch stars have an inert helium core surrounded by a shell of hydrogen fusing via the CNO cycle. They are K- and M-class stars much larger and more luminous than main-sequence stars of the same temperature.

Hertzsprung–Russell diagram for globular cluster M5. The red-giant branch runs from the thin horizontal subgiant branch to the top right, with a number of the more luminous RGB stars marked in red.

Discovery edit

 
The brightest stars in globular clusters such as NGC 288 are red giants.

Red giants were identified early in the 20th century when the use of the Hertzsprung–Russell diagram made it clear that there were two distinct types of cool stars with very different sizes: dwarfs, now formally known as the main sequence; and giants.[1][2]

The term red-giant branch came into use during the 1940s and 1950s, although initially just as a general term to refer to the red-giant region of the Hertzsprung–Russell diagram. Although the basis of a thermonuclear main-sequence lifetime, followed by a thermodynamic contraction phase to a white dwarf was understood by 1940, the internal details of the various types of giant stars were not known.[3]

In 1968, the name asymptotic giant branch (AGB) was used for a branch of stars somewhat more luminous than the bulk of red giants and more unstable, often large-amplitude variable stars such as Mira.[4] Observations of a bifurcated giant branch had been made years earlier but it was unclear how the different sequences were related.[5] By 1970, the red-giant region was well understood as being made up from subgiants, the RGB itself, the horizontal branch, and the AGB, and the evolutionary state of the stars in these regions was broadly understood.[6] The red-giant branch was described as the first giant branch in 1967, to distinguish it from the second or asymptotic giant branch,[7] and this terminology is still frequently used today.[8]

Modern stellar physics has modelled the internal processes that produce the different phases of the post-main-sequence life of moderate-mass stars,[9] with ever-increasingly complexity and precision.[10] The results of RGB research are themselves being used as the basis for research in other areas.[11]

Evolution edit

 
Evolutionary tracks for stars of different masses:
  • the 0.6 M track shows the RGB and stops at the helium flash.
  • the 1 M track shows a short but long-lasting subgiant branch and the RGB to the helium flash.
  • the 2 M track shows the subgiant branch and RGB, with a barely detectable blue loop onto the AGB.
  • the 5 M track shows a long but very brief subgiant branch, a short RGB and an extended blue loop.

When a star with a mass from about 0.4 M (solar mass) to 12 M (8 M for low-metallicity stars) exhausts its core hydrogen, it enters a phase of hydrogen shell burning during which it becomes a red giant, larger and cooler than on the main sequence. During hydrogen shell burning, the interior of the star goes through several distinct stages which are reflected in the outward appearance. The evolutionary stages vary depending primarily on the mass of the star, but also on its metallicity.

Subgiant phase edit

After a main-sequence star has exhausted its core hydrogen, it begins to fuse hydrogen in a thick shell around a core consisting largely of helium. The mass of the helium core is below the Schönberg–Chandrasekhar limit and is in thermal equilibrium, and the star is a subgiant. Any additional energy production from the shell fusion is consumed in inflating the envelope and the star cools but does not increase in luminosity.[12]

Shell hydrogen fusion continues in stars of roughly solar mass until the helium core increases in mass sufficiently that it becomes degenerate. The core then shrinks, heats up and develops a strong temperature gradient. The hydrogen shell, fusing via the temperature-sensitive CNO cycle, greatly increases its rate of energy production and the stars is considered to be at the foot of the red-giant branch. For a star the same mass as the sun, this takes approximately 2 billion years from the time that hydrogen was exhausted in the core.[13]

Subgiants more than about 2 M reach the Schönberg–Chandrasekhar limit relatively quickly before the core becomes degenerate. The core still supports its own weight thermodynamically with the help of energy from the hydrogen shell, but is no longer in thermal equilibrium. It shrinks and heats causing the hydrogen shell to become thinner and the stellar envelope to inflate. This combination decreases luminosity as the star cools towards the foot of the RGB. Before the core becomes degenerate, the outer hydrogen envelope becomes opaque which causes the star to stop cooling, increases the rate of fusion in the shell, and the star has entered the RGB. In these stars, the subgiant phase occurs within a few million years, causing an apparent gap in the Hertzsprung–Russell diagram between B-type main-sequence stars and the RGB seen in young open clusters such as Praesepe. This is the Hertzsprung gap and is actually sparsely populated with subgiant stars rapidly evolving towards red giants, in contrast to the short densely populated low-mass subgiant branch seen in older clusters such as ω Centauri.[14][15]

Ascending the red-giant branch edit

 
Sun-like stars have a degenerate core on the red-giant branch and ascend to the tip before starting core helium fusion with a flash.
 
Stars more massive than the Sun do not have a degenerate core and leave the red-giant branch before the tip when their core helium ignites without a flash.

Stars at the foot of the red-giant branch all have a similar temperature around 5,000 K, corresponding to an early to mid-K spectral type. Their luminosities range from a few times the luminosity of the sun for the least massive red giants to several thousand times as luminous for stars around 8 M.[16]

As their hydrogen shells continue to produce more helium, the cores of RGB stars increase in mass and temperature. This causes the hydrogen shell to fuse more rapidly. Stars become more luminous, larger and somewhat cooler. They are described as ascending the RGB.[17]

On the ascent of the RGB, there are a number of internal events that produce observable external features. The outer convective envelope becomes deeper and deeper as the star grows and shell energy production increases. Eventually it reaches deep enough to bring fusion products to the surface from the formerly convective core, known as the first dredge-up. This changes the surface abundance of helium, carbon, nitrogen and oxygen.[18] A noticeable clustering of stars at one point on the RGB can be detected and is known as the RGB bump. It is caused by a discontinuity in hydrogen abundance left behind by the deep convection. Shell energy production temporarily decreases at this discontinuity, effective stalling the ascent of the RGB and causing an excess of stars at that point.[19]

Tip of the red-giant branch edit

Main article: Tip of the red-giant branch

For stars with a degenerate helium core, there is a limit to this growth in size and luminosity, known as the tip of the red-giant branch, where the core reaches sufficient temperature to begin fusion. All stars that reach this point have an identical helium core mass of almost 0.5 M, and very similar stellar luminosity and temperature. These luminous stars have been used as standard candle distance indicators. Visually, the tip of the red-giant branch occurs at about absolute magnitude −3 and temperatures around 3,000 K at solar metallicity, closer to 4,000 K at very low metallicity.[16][20] Models predict a luminosity at the tip of 2000–2500 L, depending on metallicity.[21] In modern research, infrared magnitudes are more commonly used.[22]

Leaving the red-giant branch edit

A degenerate core begins fusion explosively in an event known as the helium flash, but externally there is little immediate sign of it. The energy is consumed in lifting the degeneracy in the core. The star overall becomes less luminous and hotter and migrates to the horizontal branch. All degenerate helium cores have approximately the same mass, regardless of the total stellar mass, so the helium fusion luminosity on the horizontal branch is the same. Hydrogen shell fusion can cause the total stellar luminosity to vary, but for most stars at near solar metallicity, the temperature and luminosity are very similar at the cool end of the horizontal branch. These stars form the red clump at about 5,000 K and 50 L. Less massive hydrogen envelopes cause the stars to take up a hotter and less luminous position on the horizontal branch, and this effect occurs more readily at low metallicity so that old metal-poor clusters show the most pronounced horizontal branches.[13][23]

Stars initially more massive than 2 M have non-degenerate helium cores on the red-giant branch. These stars become hot enough to start triple-alpha fusion before they reach the tip of the red-giant branch and before the core becomes degenerate. They then leave the red-giant branch and perform a blue loop before returning to join the asymptotic giant branch. Stars only a little more massive than 2 M perform a barely noticeable blue loop at a few hundred L before continuing on the AGB hardly distinguishable from their red-giant branch position. More massive stars perform extended blue loops which can reach 10,000 K or more at luminosities of thousands of L. These stars will cross the instability strip more than once and pulsate as Type I (Classical) Cepheid variables.[24]

Properties edit

The table below shows the typical lifetimes on the main sequence (MS), subgiant branch (SB) and red-giant branch (RGB), for stars with different initial masses, all at solar metallicity (Z = 0.02). Also shown are the helium core mass, surface effective temperature, radius and luminosity at the start and end of the RGB for each star. The end of the red-giant branch is defined to be when core helium ignition takes place.[8]

Mass
(M)		 MS (GYrs) Hook (MYrs) SB (MYrs) RGB
(MYrs)		 RGBfoot
 RGBend
Core mass (M) Teff (K) Radius (R) Luminosity (L) Core mass (M) Teff (K) Radius (R) Luminosity (L)
0.6 58.8 N/A 5,100 2,500 0.10 4,634 1.2 0.6 0.48 2,925 207 2,809
1.0 9.3 N/A 2,600 760 0.13 5,034 2.0 2.2 0.48 3,140 179 2,802
2.0 1.2 10 22 25 0.25 5,220 5.4 19.6 0.34 4,417 23.5 188
5.0 0.1 0.4 15 0.3 0.83 4,737 43.8 866.0 0.84 4,034 115 3,118

Intermediate-mass stars only lose a small fraction of their mass as main-sequence and subgiant stars, but lose a significant amount of mass as red giants.[25]

The mass lost by a star similar to the Sun affects the temperature and luminosity of the star when it reaches the horizontal branch, so the properties of red-clump stars can be used to determine the mass difference before and after the helium flash. Mass lost from red giants also determines the mass and properties of the white dwarfs that form subsequently. Estimates of total mass loss for stars that reach the tip of the red-giant branch are around 0.2–0.25 M. Most of this is lost within the final million years before the helium flash.[26][27]

Mass lost by more massive stars that leave the red-giant branch before the helium flash is more difficult to measure directly. The current mass of Cepheid variables such as δ Cephei can be measured accurately because there are either binaries or pulsating stars. When compared with evolutionary models, such stars appear to have lost around 20% of their mass, much of it during the blue loop and especially during pulsations on the instability strip.[28][29]

Variability edit

Some red giants are large amplitude variables. Many of the earliest-known variable stars are Mira variables with regular periods and amplitudes of several magnitudes, semiregular variables with less obvious periods or multiple periods and slightly lower amplitudes, and slow irregular variables with no obvious period. These have long been considered to be asymptotic giant branch (AGB) stars or supergiants and the red-giant branch (RGB) stars themselves were not generally considered to be variable. A few apparent exceptions were considered to be low-luminosity AGB stars.[30]

Studies in the late 20th century began to show that all giants of class M were variable with amplitudes of 10 milli-magnitudes of more, and that late-K-class giants were also likely to be variable with smaller amplitudes. Such variable stars were amongst the more luminous red giants, close to the tip of the RGB, but it was difficult to argue that they were all actually AGB stars. The stars showed a period amplitude relationship with larger-amplitude variables pulsating more slowly.[31]

Microlensing surveys in the 21st century have provided extremely accurate photometry of thousands of stars over many years. This has allowed for the discovery of many new variable stars, often of very small amplitudes. Multiple period-luminosity relationships have been discovered, grouped into regions with ridges of closely spaced parallel relationships. Some of these correspond to the known Miras and semi-regulars, but an additional class of variable star has been defined: OGLE Small Amplitude Red Giants, or OSARGs. OSARGs have amplitudes of a few thousandths of a magnitude and semi-regular periods of 10 to 100 days. The OGLE survey published up to three periods for each OSARG, indicating a complex combination of pulsations. Many thousands of OSARGs were quickly detected in the Magellanic Clouds, both AGB and RGB stars.[32] A catalog has since been published of 192,643 OSARGs in the direction of the Milky Way central bulge. Although around a quarter of Magellanic Cloud OSARgs show long secondary periods, very few of the galactic OSARGs do.[33]

The RGB OSARGs follow three closely spaced period-luminosity relations, corresponding to the first, second and third overtones of radial pulsation models for stars of certain masses and luminosities, but that dipole and quadrupole non-radial pulsations are also present leading to the semi-regular nature of the variations.[34] The fundamental mode does not appear, and the underlying cause of the excitation is not known. Stochastic convection has been suggested as a cause, similar to solar-like oscillations.[32]

Two additional types of variation have been discovered in RGB stars: long secondary periods, which are associated with other variations but can show larger amplitudes with periods of hundreds or thousands of days; and ellipsoidal variations. The cause of the long secondary periods is unknown, but it has been proposed that they are due to interactions with low-mass companions in close orbits.[35] The ellipsoidal variations are also thought to be created in binary systems, in this case contact binaries where distorted stars cause strictly periodic variations as they orbit.[36]

References edit

  1. ^ Adams, W. S.; Joy, A. H.; Stromberg, G.; Burwell, C. G. (1921). "The parallaxes of 1646 stars derived by the spectroscopic method". Astrophysical Journal. 53: 13. Bibcode:1921ApJ....53...13A. doi:10.1086/142584.
  2. ^ Trumpler, R. J. (1925). "Spectral Types in Open Clusters". Publications of the Astronomical Society of the Pacific. 37 (220): 307. Bibcode:1925PASP...37..307T. doi:10.1086/123509.
  3. ^ Gamow, G. (1939). "Physical Possibilities of Stellar Evolution". Physical Review. 55 (8): 718–725. Bibcode:1939PhRv...55..718G. doi:10.1103/PhysRev.55.718.
  4. ^ Sandage, Allan; Katem, Basil; Kristian, Jerome (1968). "An Indication of Gaps in the Giant Branch of the Globular Cluster M15". Astrophysical Journal. 153: L129. Bibcode:1968ApJ...153L.129S. doi:10.1086/180237.
  5. ^ Arp, Halton C.; Baum, William A.; Sandage, Allan R. (1953). "The color-magnitude diagram of the globular cluster M 92". Astronomical Journal. 58: 4. Bibcode:1953AJ.....58....4A. doi:10.1086/106800.
  6. ^ Strom, S. E.; Strom, K. M.; Rood, R. T.; Iben, I. (1970). "On the Evolutionary Status of Stars above the Horizontal Branch in Globular Clusters". Astronomy and Astrophysics. 8: 243. Bibcode:1970A&A.....8..243S.
  7. ^ Iben, Icko (1967). "Stellar Evolution Within and off the Main Sequence". Annual Review of Astronomy and Astrophysics. 5: 571–626. Bibcode:1967ARA&A...5..571I. doi:10.1146/annurev.aa.05.090167.003035.
  8. ^ a b 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.
  9. ^ Vassiliadis, E.; Wood, P. R. (1993). "Evolution of low- and intermediate-mass stars to the end of the asymptotic giant branch with mass loss". Astrophysical Journal. 413: 641. Bibcode:1993ApJ...413..641V. doi:10.1086/173033.
  10. ^ Marigo, P.; Girardi, L.; Bressan, A.; Groenewegen, M. A. T.; Silva, L.; Granato, G. L. (2008). "Evolution of asymptotic giant branch stars". Astronomy and Astrophysics. 482 (3): 883–905. arXiv:0711.4922. Bibcode:2008A&A...482..883M. doi:10.1051/0004-6361:20078467. S2CID 15076538.
  11. ^ Rizzi, Luca; Tully, R. Brent; Makarov, Dmitry; Makarova, Lidia; Dolphin, Andrew E.; Sakai, Shoko; Shaya, Edward J. (2007). "Tip of the Red Giant Branch Distances. II. Zero-Point Calibration". The Astrophysical Journal. 661 (2): 815–829. arXiv:astro-ph/0701518. Bibcode:2007ApJ...661..815R. doi:10.1086/516566. S2CID 12864247.
  12. ^ Catelan, Márcio; Roig, Fernando; Alcaniz, Jailson; de la Reza, Ramiro; Lopes, Dalton (2007). Structure and Evolution of Low-Mass Stars: An Overview and Some Open Problems. GRADUATE SCHOOL IN ASTRONOMY: XI Special Courses at the National Observatory of Rio de Janeiro (XI CCE). AIP Conference Proceedings. Vol. 930. pp. 39–90. arXiv:astro-ph/0703724. Bibcode:2007AIPC..930...39C. doi:10.1063/1.2790333. S2CID 15599804.
  13. ^ a b Salaris, Maurizio; Cassisi, Santi (2005). Evolution of Stars and Stellar Populations. p. 400. Bibcode:2005essp.book.....S.
  14. ^ Mermilliod, J. C. (1981). "Comparative studies of young open clusters. III – Empirical isochronous curves and the zero age main sequence". Astronomy and Astrophysics. 97: 235. Bibcode:1981A&A....97..235M.
  15. ^ Bedin, Luigi R.; Piotto, Giampaolo; Anderson, Jay; Cassisi, Santi; King, Ivan R.; Momany, Yazan; Carraro, Giovanni (2004). "Ω Centauri: The Population Puzzle Goes Deeper". The Astrophysical Journal. 605 (2): L125. arXiv:astro-ph/0403112. Bibcode:2004ApJ...605L.125B. doi:10.1086/420847. S2CID 2799751.
  16. ^ a b Vandenberg, Don A.; Bergbusch, Peter A.; Dowler, Patrick D. (2006). "The Victoria-Regina Stellar Models: Evolutionary Tracks and Isochrones for a Wide Range in Mass and Metallicity that Allow for Empirically Constrained Amounts of Convective Core Overshooting". The Astrophysical Journal Supplement Series. 162 (2): 375–387. arXiv:astro-ph/0510784. Bibcode:2006ApJS..162..375V. doi:10.1086/498451. S2CID 1791448.
  17. ^ Hekker, S.; Gilliland, R. L.; Elsworth, Y.; Chaplin, W. J.; De Ridder, J.; Stello, D.; Kallinger, T.; Ibrahim, K. A.; Klaus, T. C.; Li, J. (2011). "Characterization of red giant stars in the public Kepler data". Monthly Notices of the Royal Astronomical Society. 414 (3): 2594. arXiv:1103.0141. Bibcode:2011MNRAS.414.2594H. doi:10.1111/j.1365-2966.2011.18574.x. S2CID 118513871.
  18. ^ Stoesz, Jeffrey A.; Herwig, Falk (2003). "Oxygen isotopic ratios in first dredge-up red giant stars and nuclear reaction rate uncertainties revisited". Monthly Notices of the Royal Astronomical Society. 340 (3): 763. arXiv:astro-ph/0212128. Bibcode:2003MNRAS.340..763S. doi:10.1046/j.1365-8711.2003.06332.x. S2CID 14107804.
  19. ^ Cassisi, S.; Marín-Franch, A.; Salaris, M.; Aparicio, A.; Monelli, M.; Pietrinferni, A. (2011). "The magnitude difference between the main sequence turn off and the red giant branch bump in Galactic globular clusters". Astronomy & Astrophysics. 527: A59. arXiv:1012.0419. Bibcode:2011A&A...527A..59C. doi:10.1051/0004-6361/201016066. S2CID 56067351.
  20. ^ Lee, Myung Gyoon; Freedman, Wendy L.; Madore, Barry F. (1993). "The Tip of the Red Giant Branch as a Distance Indicator for Resolved Galaxies". Astrophysical Journal. 417: 553. Bibcode:1993ApJ...417..553L. doi:10.1086/173334.
  21. ^ Salaris, Maurizio; Cassisi, Santi (1997). "The 'tip' of the red giant branch as a distance indicator: Results from evolutionary models". Monthly Notices of the Royal Astronomical Society. 289 (2): 406. arXiv:astro-ph/9703186. Bibcode:1997MNRAS.289..406S. doi:10.1093/mnras/289.2.406. S2CID 18796954.
  22. ^ Conn, A. R.; Ibata, R. A.; Lewis, G. F.; Parker, Q. A.; Zucker, D. B.; Martin, N. F.; McConnachie, A. W.; Irwin, M. J.; Tanvir, N.; Fardal, M. A.; Ferguson, A. M. N.; Chapman, S. C.; Valls-Gabaud, D. (2012). "A Bayesian Approach to Locating the Red Giant Branch Tip Magnitude. Ii. Distances to the Satellites of M31". The Astrophysical Journal. 758 (1): 11. arXiv:1209.4952. Bibcode:2012ApJ...758...11C. doi:10.1088/0004-637X/758/1/11. S2CID 53556162.
  23. ^ d'Antona, F.; Caloi, V.; Montalbán, J.; Ventura, P.; Gratton, R. (2002). "Helium variation due to self-pollution among Globular Cluster stars". Astronomy and Astrophysics. 395: 69–76. arXiv:astro-ph/0209331. Bibcode:2002A&A...395...69D. doi:10.1051/0004-6361:20021220. S2CID 15262502.
  24. ^ Bono, Giuseppe; Caputo, Filippina; Cassisi, Santi; Marconi, Marcella; Piersanti, Luciano; Tornambè, Amedeo (2000). "Intermediate-Mass Star Models with Different Helium and Metal Contents". The Astrophysical Journal. 543 (2): 955. arXiv:astro-ph/0006251. Bibcode:2000ApJ...543..955B. doi:10.1086/317156. S2CID 18898755.
  25. ^ Meynet, G.; Mermilliod, J.-C.; Maeder, A. (1993). "New dating of galactic open clusters". Astronomy and Astrophysics Supplement Series. 98: 477. Bibcode:1993A&AS...98..477M.
  26. ^ Origlia, Livia; Ferraro, Francesco R.; Fusi Pecci, Flavio; Rood, Robert T. (2002). "ISOCAM Observations of Galactic Globular Clusters: Mass Loss along the Red Giant Branch". The Astrophysical Journal. 571 (1): 458–468. arXiv:astro-ph/0201445. Bibcode:2002ApJ...571..458O. doi:10.1086/339857. S2CID 18299018.
  27. ^ McDonald, I.; Boyer, M. L.; Van Loon, J. Th.; Zijlstra, A. A.; Hora, J. L.; Babler, B.; Block, M.; Gordon, K.; Meade, M.; Meixner, M.; Misselt, K.; Robitaille, T.; Sewiło, M.; Shiao, B.; Whitney, B. (2011). "Fundamental Parameters, Integrated Red Giant Branch Mass Loss, and Dust Production in the Galactic Globular Cluster 47 Tucanae". The Astrophysical Journal Supplement. 193 (2): 23. arXiv:1101.1095. Bibcode:2011ApJS..193...23M. doi:10.1088/0067-0049/193/2/23. S2CID 119266025.
  28. ^ Xu, H. Y.; Li, Y. (2004). "Blue loops of intermediate mass stars . I. CNO cycles and blue loops". Astronomy and Astrophysics. 418: 213–224. Bibcode:2004A&A...418..213X. doi:10.1051/0004-6361:20040024.
  29. ^ Neilson, H. R.; Cantiello, M.; Langer, N. (2011). "The Cepheid mass discrepancy and pulsation-driven mass loss". Astronomy & Astrophysics. 529: L9. arXiv:1104.1638. Bibcode:2011A&A...529L...9N. doi:10.1051/0004-6361/201116920. S2CID 119180438.
  30. ^ Kiss, L. L.; Bedding, T. R. (2003). "Red variables in the OGLE-II data base – I. Pulsations and period-luminosity relations below the tip of the red giant branch of the Large Magellanic Cloud". Monthly Notices of the Royal Astronomical Society. 343 (3): L79. arXiv:astro-ph/0306426. Bibcode:2003MNRAS.343L..79K. doi:10.1046/j.1365-8711.2003.06931.x. S2CID 2383837.
  31. ^ Jorissen, A.; Mowlavi, N.; Sterken, C.; Manfroid, J. (1997). "The onset of photometric variability in red giant stars". Astronomy and Astrophysics. 324: 578. Bibcode:1997A&A...324..578J.
  32. ^ a b Soszynski, I.; Dziembowski, W. A.; Udalski, A.; Kubiak, M.; Szymanski, M. K.; Pietrzynski, G.; Wyrzykowski, L.; Szewczyk, O.; Ulaczyk, K. (2007). "The Optical Gravitational Lensing Experiment. Period—Luminosity Relations of Variable Red Giant Stars". Acta Astronomica. 57: 201. arXiv:0710.2780. Bibcode:2007AcA....57..201S.
  33. ^ Soszyński, I.; Udalski, A.; Szymański, M. K.; Kubiak, M.; Pietrzyński, G.; Wyrzykowski, Ł.; Ulaczyk, K.; Poleski, R.; Kozłowski, S.; Pietrukowicz, P.; Skowron, J. (2013). "The Optical Gravitational Lensing Experiment. The OGLE-III Catalog of Variable Stars. XV. Long-Period Variables in the Galactic Bulge". Acta Astronomica. 63 (1): 21. arXiv:1304.2787. Bibcode:2013AcA....63...21S.
  34. ^ Takayama, M.; Saio, H.; Ita, Y. (2013). "On the pulsation modes and masses of RGB OSARGs". EPJ Web of Conferences. 43: 03013. Bibcode:2013EPJWC..4303013T. doi:10.1051/epjconf/20134303013.
  35. ^ Nicholls, C. P.; Wood, P. R.; Cioni, M.-R. L.; Soszyński, I. (2009). "Long Secondary Periods in variable red giants". Monthly Notices of the Royal Astronomical Society. 399 (4): 2063–2078. arXiv:0907.2975. Bibcode:2009MNRAS.399.2063N. doi:10.1111/j.1365-2966.2009.15401.x. S2CID 19019968.
  36. ^ Nicholls, C. P.; Wood, P. R. (2012). "Eccentric ellipsoidal red giant binaries in the LMC: Complete orbital solutions and comments on interaction at periastron". Monthly Notices of the Royal Astronomical Society. 421 (3): 2616. arXiv:1201.1043. Bibcode:2012MNRAS.421.2616N. doi:10.1111/j.1365-2966.2012.20492.x. S2CID 59464524.

Bibliography edit

  • Vassiliadis, E.; Wood, P. R. (1993). "Evolution of low- and intermediate-mass stars to the end of the asymptotic giant branch with mass loss". Astrophysical Journal. 413: 641. Bibcode:1993ApJ...413..641V. doi:10.1086/173033.
  • Girardi, L.; Bressan, A.; Bertelli, G.; Chiosi, C. (2000). "Evolutionary tracks and isochrones for low- and intermediate-mass stars: From 0.15 to 7 M☉, and from Z=0.0004 to 0.03". Astronomy and Astrophysics Supplement Series. 141 (3): 371–383. arXiv:astro-ph/9910164. Bibcode:2000A&AS..141..371G. doi:10.1051/aas:2000126. S2CID 14566232.

External links edit

  • Post-main sequence evolution through helium burning
  • Long period variables – period luminosity relations and classification in the Gaia Mission

February 15, 2024
giant, branch, giant, branch, sometimes, called, first, giant, branch, portion, giant, branch, before, helium, ignition, occurs, course, stellar, evolution, stage, that, follows, main, sequence, intermediate, mass, stars, giant, branch, stars, have, inert, hel. The red giant branch RGB sometimes called the first giant branch is the portion of the giant branch before helium ignition occurs in the course of stellar evolution It is a stage that follows the main sequence for low to intermediate mass stars Red giant branch stars have an inert helium core surrounded by a shell of hydrogen fusing via the CNO cycle They are K and M class stars much larger and more luminous than main sequence stars of the same temperature Hertzsprung Russell diagram for globular cluster M5 The red giant branch runs from the thin horizontal subgiant branch to the top right with a number of the more luminous RGB stars marked in red Contents 1 Discovery 2 Evolution 2 1 Subgiant phase 2 2 Ascending the red giant branch 2 3 Tip of the red giant branch 2 4 Leaving the red giant branch 2 5 Properties 3 Variability 4 References 5 Bibliography 6 External linksDiscovery edit nbsp The brightest stars in globular clusters such as NGC 288 are red giants Red giants were identified early in the 20th century when the use of the Hertzsprung Russell diagram made it clear that there were two distinct types of cool stars with very different sizes dwarfs now formally known as the main sequence and giants 1 2 The term red giant branch came into use during the 1940s and 1950s although initially just as a general term to refer to the red giant region of the Hertzsprung Russell diagram Although the basis of a thermonuclear main sequence lifetime followed by a thermodynamic contraction phase to a white dwarf was understood by 1940 the internal details of the various types of giant stars were not known 3 In 1968 the name asymptotic giant branch AGB was used for a branch of stars somewhat more luminous than the bulk of red giants and more unstable often large amplitude variable stars such as Mira 4 Observations of a bifurcated giant branch had been made years earlier but it was unclear how the different sequences were related 5 By 1970 the red giant region was well understood as being made up from subgiants the RGB itself the horizontal branch and the AGB and the evolutionary state of the stars in these regions was broadly understood 6 The red giant branch was described as the first giant branch in 1967 to distinguish it from the second or asymptotic giant branch 7 and this terminology is still frequently used today 8 Modern stellar physics has modelled the internal processes that produce the different phases of the post main sequence life of moderate mass stars 9 with ever increasingly complexity and precision 10 The results of RGB research are themselves being used as the basis for research in other areas 11 Evolution edit nbsp Evolutionary tracks for stars of different masses the 0 6 M track shows the RGB and stops at the helium flash the 1 M track shows a short but long lasting subgiant branch and the RGB to the helium flash the 2 M track shows the subgiant branch and RGB with a barely detectable blue loop onto the AGB the 5 M track shows a long but very brief subgiant branch a short RGB and an extended blue loop When a star with a mass from about 0 4 M solar mass to 12 M 8 M for low metallicity stars exhausts its core hydrogen it enters a phase of hydrogen shell burning during which it becomes a red giant larger and cooler than on the main sequence During hydrogen shell burning the interior of the star goes through several distinct stages which are reflected in the outward appearance The evolutionary stages vary depending primarily on the mass of the star but also on its metallicity Subgiant phase edit After a main sequence star has exhausted its core hydrogen it begins to fuse hydrogen in a thick shell around a core consisting largely of helium The mass of the helium core is below the Schonberg Chandrasekhar limit and is in thermal equilibrium and the star is a subgiant Any additional energy production from the shell fusion is consumed in inflating the envelope and the star cools but does not increase in luminosity 12 Shell hydrogen fusion continues in stars of roughly solar mass until the helium core increases in mass sufficiently that it becomes degenerate The core then shrinks heats up and develops a strong temperature gradient The hydrogen shell fusing via the temperature sensitive CNO cycle greatly increases its rate of energy production and the stars is considered to be at the foot of the red giant branch For a star the same mass as the sun this takes approximately 2 billion years from the time that hydrogen was exhausted in the core 13 Subgiants more than about 2 M reach the Schonberg Chandrasekhar limit relatively quickly before the core becomes degenerate The core still supports its own weight thermodynamically with the help of energy from the hydrogen shell but is no longer in thermal equilibrium It shrinks and heats causing the hydrogen shell to become thinner and the stellar envelope to inflate This combination decreases luminosity as the star cools towards the foot of the RGB Before the core becomes degenerate the outer hydrogen envelope becomes opaque which causes the star to stop cooling increases the rate of fusion in the shell and the star has entered the RGB In these stars the subgiant phase occurs within a few million years causing an apparent gap in the Hertzsprung Russell diagram between B type main sequence stars and the RGB seen in young open clusters such as Praesepe This is the Hertzsprung gap and is actually sparsely populated with subgiant stars rapidly evolving towards red giants in contrast to the short densely populated low mass subgiant branch seen in older clusters such as w Centauri 14 15 Ascending the red giant branch edit nbsp Sun like stars have a degenerate core on the red giant branch and ascend to the tip before starting core helium fusion with a flash nbsp Stars more massive than the Sun do not have a degenerate core and leave the red giant branch before the tip when their core helium ignites without a flash Stars at the foot of the red giant branch all have a similar temperature around 5 000 K corresponding to an early to mid K spectral type Their luminosities range from a few times the luminosity of the sun for the least massive red giants to several thousand times as luminous for stars around 8 M 16 As their hydrogen shells continue to produce more helium the cores of RGB stars increase in mass and temperature This causes the hydrogen shell to fuse more rapidly Stars become more luminous larger and somewhat cooler They are described as ascending the RGB 17 On the ascent of the RGB there are a number of internal events that produce observable external features The outer convective envelope becomes deeper and deeper as the star grows and shell energy production increases Eventually it reaches deep enough to bring fusion products to the surface from the formerly convective core known as the first dredge up This changes the surface abundance of helium carbon nitrogen and oxygen 18 A noticeable clustering of stars at one point on the RGB can be detected and is known as the RGB bump It is caused by a discontinuity in hydrogen abundance left behind by the deep convection Shell energy production temporarily decreases at this discontinuity effective stalling the ascent of the RGB and causing an excess of stars at that point 19 Tip of the red giant branch edit Main article Tip of the red giant branch For stars with a degenerate helium core there is a limit to this growth in size and luminosity known as the tip of the red giant branch where the core reaches sufficient temperature to begin fusion All stars that reach this point have an identical helium core mass of almost 0 5 M and very similar stellar luminosity and temperature These luminous stars have been used as standard candle distance indicators Visually the tip of the red giant branch occurs at about absolute magnitude 3 and temperatures around 3 000 K at solar metallicity closer to 4 000 K at very low metallicity 16 20 Models predict a luminosity at the tip of 2000 2500 L depending on metallicity 21 In modern research infrared magnitudes are more commonly used 22 Leaving the red giant branch edit A degenerate core begins fusion explosively in an event known as the helium flash but externally there is little immediate sign of it The energy is consumed in lifting the degeneracy in the core The star overall becomes less luminous and hotter and migrates to the horizontal branch All degenerate helium cores have approximately the same mass regardless of the total stellar mass so the helium fusion luminosity on the horizontal branch is the same Hydrogen shell fusion can cause the total stellar luminosity to vary but for most stars at near solar metallicity the temperature and luminosity are very similar at the cool end of the horizontal branch These stars form the red clump at about 5 000 K and 50 L Less massive hydrogen envelopes cause the stars to take up a hotter and less luminous position on the horizontal branch and this effect occurs more readily at low metallicity so that old metal poor clusters show the most pronounced horizontal branches 13 23 Stars initially more massive than 2 M have non degenerate helium cores on the red giant branch These stars become hot enough to start triple alpha fusion before they reach the tip of the red giant branch and before the core becomes degenerate They then leave the red giant branch and perform a blue loop before returning to join the asymptotic giant branch Stars only a little more massive than 2 M perform a barely noticeable blue loop at a few hundred L before continuing on the AGB hardly distinguishable from their red giant branch position More massive stars perform extended blue loops which can reach 10 000 K or more at luminosities of thousands of L These stars will cross the instability strip more than once and pulsate as Type I Classical Cepheid variables 24 Properties edit The table below shows the typical lifetimes on the main sequence MS subgiant branch SB and red giant branch RGB for stars with different initial masses all at solar metallicity Z 0 02 Also shown are the helium core mass surface effective temperature radius and luminosity at the start and end of the RGB for each star The end of the red giant branch is defined to be when core helium ignition takes place 8 Mass M MS GYrs Hook MYrs SB MYrs RGB MYrs RGBfoot RGBendCore mass M Teff K Radius R Luminosity L Core mass M Teff K Radius R Luminosity L 0 6 58 8 N A 5 100 2 500 0 10 4 634 1 2 0 6 0 48 2 925 207 2 8091 0 9 3 N A 2 600 760 0 13 5 034 2 0 2 2 0 48 3 140 179 2 8022 0 1 2 10 22 25 0 25 5 220 5 4 19 6 0 34 4 417 23 5 1885 0 0 1 0 4 15 0 3 0 83 4 737 43 8 866 0 0 84 4 034 115 3 118Intermediate mass stars only lose a small fraction of their mass as main sequence and subgiant stars but lose a significant amount of mass as red giants 25 The mass lost by a star similar to the Sun affects the temperature and luminosity of the star when it reaches the horizontal branch so the properties of red clump stars can be used to determine the mass difference before and after the helium flash Mass lost from red giants also determines the mass and properties of the white dwarfs that form subsequently Estimates of total mass loss for stars that reach the tip of the red giant branch are around 0 2 0 25 M Most of this is lost within the final million years before the helium flash 26 27 Mass lost by more massive stars that leave the red giant branch before the helium flash is more difficult to measure directly The current mass of Cepheid variables such as d Cephei can be measured accurately because there are either binaries or pulsating stars When compared with evolutionary models such stars appear to have lost around 20 of their mass much of it during the blue loop and especially during pulsations on the instability strip 28 29 Variability editSome red giants are large amplitude variables Many of the earliest known variable stars are Mira variables with regular periods and amplitudes of several magnitudes semiregular variables with less obvious periods or multiple periods and slightly lower amplitudes and slow irregular variables with no obvious period These have long been considered to be asymptotic giant branch AGB stars or supergiants and the red giant branch RGB stars themselves were not generally considered to be variable A few apparent exceptions were considered to be low luminosity AGB stars 30 Studies in the late 20th century began to show that all giants of class M were variable with amplitudes of 10 milli magnitudes of more and that late K class giants were also likely to be variable with smaller amplitudes Such variable stars were amongst the more luminous red giants close to the tip of the RGB but it was difficult to argue that they were all actually AGB stars The stars showed a period amplitude relationship with larger amplitude variables pulsating more slowly 31 Microlensing surveys in the 21st century have provided extremely accurate photometry of thousands of stars over many years This has allowed for the discovery of many new variable stars often of very small amplitudes Multiple period luminosity relationships have been discovered grouped into regions with ridges of closely spaced parallel relationships Some of these correspond to the known Miras and semi regulars but an additional class of variable star has been defined OGLE Small Amplitude Red Giants or OSARGs OSARGs have amplitudes of a few thousandths of a magnitude and semi regular periods of 10 to 100 days The OGLE survey published up to three periods for each OSARG indicating a complex combination of pulsations Many thousands of OSARGs were quickly detected in the Magellanic Clouds both AGB and RGB stars 32 A catalog has since been published of 192 643 OSARGs in the direction of the Milky Way central bulge Although around a quarter of Magellanic Cloud OSARgs show long secondary periods very few of the galactic OSARGs do 33 The RGB OSARGs follow three closely spaced period luminosity relations corresponding to the first second and third overtones of radial pulsation models for stars of certain masses and luminosities but that dipole and quadrupole non radial pulsations are also present leading to the semi regular nature of the variations 34 The fundamental mode does not appear and the underlying cause of the excitation is not known Stochastic convection has been suggested as a cause similar to solar like oscillations 32 Two additional types of variation have been discovered in RGB stars long secondary periods which are associated with other variations but can show larger amplitudes with periods of hundreds or thousands of days and ellipsoidal variations The cause of the long secondary periods is unknown but it has been proposed that they are due to interactions with low mass companions in close orbits 35 The ellipsoidal variations are also thought to be created in binary systems in this case contact binaries where distorted stars cause strictly periodic variations as they orbit 36 References edit Adams W S Joy A H Stromberg G Burwell C G 1921 The parallaxes of 1646 stars derived by the spectroscopic method Astrophysical Journal 53 13 Bibcode 1921ApJ 53 13A doi 10 1086 142584 Trumpler R J 1925 Spectral Types in Open Clusters Publications of the Astronomical Society of the Pacific 37 220 307 Bibcode 1925PASP 37 307T doi 10 1086 123509 Gamow G 1939 Physical Possibilities of Stellar Evolution Physical Review 55 8 718 725 Bibcode 1939PhRv 55 718G doi 10 1103 PhysRev 55 718 Sandage Allan Katem Basil Kristian Jerome 1968 An Indication of Gaps in the Giant Branch of the Globular Cluster M15 Astrophysical Journal 153 L129 Bibcode 1968ApJ 153L 129S doi 10 1086 180237 Arp Halton C Baum William A Sandage Allan R 1953 The color magnitude diagram of the globular cluster M 92 Astronomical Journal 58 4 Bibcode 1953AJ 58 4A doi 10 1086 106800 Strom S E Strom K M Rood R T Iben I 1970 On the Evolutionary Status of Stars above the Horizontal Branch in Globular Clusters Astronomy and Astrophysics 8 243 Bibcode 1970A amp A 8 243S Iben Icko 1967 Stellar Evolution Within and off the Main Sequence Annual Review of Astronomy and Astrophysics 5 571 626 Bibcode 1967ARA amp A 5 571I doi 10 1146 annurev aa 05 090167 003035 a b Pols Onno R Schroder 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 Vassiliadis E Wood P R 1993 Evolution of low and intermediate mass stars to the end of the asymptotic giant branch with mass loss Astrophysical Journal 413 641 Bibcode 1993ApJ 413 641V doi 10 1086 173033 Marigo P Girardi L Bressan A Groenewegen M A T Silva L Granato G L 2008 Evolution of asymptotic giant branch stars Astronomy and Astrophysics 482 3 883 905 arXiv 0711 4922 Bibcode 2008A amp A 482 883M doi 10 1051 0004 6361 20078467 S2CID 15076538 Rizzi Luca Tully R Brent Makarov Dmitry Makarova Lidia Dolphin Andrew E Sakai Shoko Shaya Edward J 2007 Tip of the Red Giant Branch Distances II Zero Point Calibration The Astrophysical Journal 661 2 815 829 arXiv astro ph 0701518 Bibcode 2007ApJ 661 815R doi 10 1086 516566 S2CID 12864247 Catelan Marcio Roig Fernando Alcaniz Jailson de la Reza Ramiro Lopes Dalton 2007 Structure and Evolution of Low Mass Stars An Overview and Some Open Problems GRADUATE SCHOOL IN ASTRONOMY XI Special Courses at the National Observatory of Rio de Janeiro XI CCE AIP Conference Proceedings Vol 930 pp 39 90 arXiv astro ph 0703724 Bibcode 2007AIPC 930 39C doi 10 1063 1 2790333 S2CID 15599804 a b Salaris Maurizio Cassisi Santi 2005 Evolution of Stars and Stellar Populations p 400 Bibcode 2005essp book S Mermilliod J C 1981 Comparative studies of young open clusters III Empirical isochronous curves and the zero age main sequence Astronomy and Astrophysics 97 235 Bibcode 1981A amp A 97 235M Bedin Luigi R Piotto Giampaolo Anderson Jay Cassisi Santi King Ivan R Momany Yazan Carraro Giovanni 2004 W Centauri The Population Puzzle Goes Deeper The Astrophysical Journal 605 2 L125 arXiv astro ph 0403112 Bibcode 2004ApJ 605L 125B doi 10 1086 420847 S2CID 2799751 a b Vandenberg Don A Bergbusch Peter A Dowler Patrick D 2006 The Victoria Regina Stellar Models Evolutionary Tracks and Isochrones for a Wide Range in Mass and Metallicity that Allow for Empirically Constrained Amounts of Convective Core Overshooting The Astrophysical Journal Supplement Series 162 2 375 387 arXiv astro ph 0510784 Bibcode 2006ApJS 162 375V doi 10 1086 498451 S2CID 1791448 Hekker S Gilliland R L Elsworth Y Chaplin W J De Ridder J Stello D Kallinger T Ibrahim K A Klaus T C Li J 2011 Characterization of red giant stars in the public Kepler data Monthly Notices of the Royal Astronomical Society 414 3 2594 arXiv 1103 0141 Bibcode 2011MNRAS 414 2594H doi 10 1111 j 1365 2966 2011 18574 x S2CID 118513871 Stoesz Jeffrey A Herwig Falk 2003 Oxygen isotopic ratios in first dredge up red giant stars and nuclear reaction rate uncertainties revisited Monthly Notices of the Royal Astronomical Society 340 3 763 arXiv astro ph 0212128 Bibcode 2003MNRAS 340 763S doi 10 1046 j 1365 8711 2003 06332 x S2CID 14107804 Cassisi S Marin Franch A Salaris M Aparicio A Monelli M Pietrinferni A 2011 The magnitude difference between the main sequence turn off and the red giant branch bump in Galactic globular clusters Astronomy amp Astrophysics 527 A59 arXiv 1012 0419 Bibcode 2011A amp A 527A 59C doi 10 1051 0004 6361 201016066 S2CID 56067351 Lee Myung Gyoon Freedman Wendy L Madore Barry F 1993 The Tip of the Red Giant Branch as a Distance Indicator for Resolved Galaxies Astrophysical Journal 417 553 Bibcode 1993ApJ 417 553L doi 10 1086 173334 Salaris Maurizio Cassisi Santi 1997 The tip of the red giant branch as a distance indicator Results from evolutionary models Monthly Notices of the Royal Astronomical Society 289 2 406 arXiv astro ph 9703186 Bibcode 1997MNRAS 289 406S doi 10 1093 mnras 289 2 406 S2CID 18796954 Conn A R Ibata R A Lewis G F Parker Q A Zucker D B Martin N F McConnachie A W Irwin M J Tanvir N Fardal M A Ferguson A M N Chapman S C Valls Gabaud D 2012 A Bayesian Approach to Locating the Red Giant Branch Tip Magnitude Ii Distances to the Satellites of M31 The Astrophysical Journal 758 1 11 arXiv 1209 4952 Bibcode 2012ApJ 758 11C doi 10 1088 0004 637X 758 1 11 S2CID 53556162 d Antona F Caloi V Montalban J Ventura P Gratton R 2002 Helium variation due to self pollution among Globular Cluster stars Astronomy and Astrophysics 395 69 76 arXiv astro ph 0209331 Bibcode 2002A amp A 395 69D doi 10 1051 0004 6361 20021220 S2CID 15262502 Bono Giuseppe Caputo Filippina Cassisi Santi Marconi Marcella Piersanti Luciano Tornambe Amedeo 2000 Intermediate Mass Star Models with Different Helium and Metal Contents The Astrophysical Journal 543 2 955 arXiv astro ph 0006251 Bibcode 2000ApJ 543 955B doi 10 1086 317156 S2CID 18898755 Meynet G Mermilliod J C Maeder A 1993 New dating of galactic open clusters Astronomy and Astrophysics Supplement Series 98 477 Bibcode 1993A amp AS 98 477M Origlia Livia Ferraro Francesco R Fusi Pecci Flavio Rood Robert T 2002 ISOCAM Observations of Galactic Globular Clusters Mass Loss along the Red Giant Branch The Astrophysical Journal 571 1 458 468 arXiv astro ph 0201445 Bibcode 2002ApJ 571 458O doi 10 1086 339857 S2CID 18299018 McDonald I Boyer M L Van Loon J Th Zijlstra A A Hora J L Babler B Block M Gordon K Meade M Meixner M Misselt K Robitaille T Sewilo M Shiao B Whitney B 2011 Fundamental Parameters Integrated Red Giant Branch Mass Loss and Dust Production in the Galactic Globular Cluster 47 Tucanae The Astrophysical Journal Supplement 193 2 23 arXiv 1101 1095 Bibcode 2011ApJS 193 23M doi 10 1088 0067 0049 193 2 23 S2CID 119266025 Xu H Y Li Y 2004 Blue loops of intermediate mass stars I CNO cycles and blue loops Astronomy and Astrophysics 418 213 224 Bibcode 2004A amp A 418 213X doi 10 1051 0004 6361 20040024 Neilson H R Cantiello M Langer N 2011 The Cepheid mass discrepancy and pulsation driven mass loss Astronomy amp Astrophysics 529 L9 arXiv 1104 1638 Bibcode 2011A amp A 529L 9N doi 10 1051 0004 6361 201116920 S2CID 119180438 Kiss L L Bedding T R 2003 Red variables in the OGLE II data base I Pulsations and period luminosity relations below the tip of the red giant branch of the Large Magellanic Cloud Monthly Notices of the Royal Astronomical Society 343 3 L79 arXiv astro ph 0306426 Bibcode 2003MNRAS 343L 79K doi 10 1046 j 1365 8711 2003 06931 x S2CID 2383837 Jorissen A Mowlavi N Sterken C Manfroid J 1997 The onset of photometric variability in red giant stars Astronomy and Astrophysics 324 578 Bibcode 1997A amp A 324 578J a b Soszynski I Dziembowski W A Udalski A Kubiak M Szymanski M K Pietrzynski G Wyrzykowski L Szewczyk O Ulaczyk K 2007 The Optical Gravitational Lensing Experiment Period Luminosity Relations of Variable Red Giant Stars Acta Astronomica 57 201 arXiv 0710 2780 Bibcode 2007AcA 57 201S Soszynski I Udalski A Szymanski M K Kubiak M Pietrzynski G Wyrzykowski L Ulaczyk K Poleski R Kozlowski S Pietrukowicz P Skowron J 2013 The Optical Gravitational Lensing Experiment The OGLE III Catalog of Variable Stars XV Long Period Variables in the Galactic Bulge Acta Astronomica 63 1 21 arXiv 1304 2787 Bibcode 2013AcA 63 21S Takayama M Saio H Ita Y 2013 On the pulsation modes and masses of RGB OSARGs EPJ Web of Conferences 43 03013 Bibcode 2013EPJWC 4303013T doi 10 1051 epjconf 20134303013 Nicholls C P Wood P R Cioni M R L Soszynski I 2009 Long Secondary Periods in variable red giants Monthly Notices of the Royal Astronomical Society 399 4 2063 2078 arXiv 0907 2975 Bibcode 2009MNRAS 399 2063N doi 10 1111 j 1365 2966 2009 15401 x S2CID 19019968 Nicholls C P Wood P R 2012 Eccentric ellipsoidal red giant binaries in the LMC Complete orbital solutions and comments on interaction at periastron Monthly Notices of the Royal Astronomical Society 421 3 2616 arXiv 1201 1043 Bibcode 2012MNRAS 421 2616N doi 10 1111 j 1365 2966 2012 20492 x S2CID 59464524 Bibliography editVassiliadis E Wood P R 1993 Evolution of low and intermediate mass stars to the end of the asymptotic giant branch with mass loss Astrophysical Journal 413 641 Bibcode 1993ApJ 413 641V doi 10 1086 173033 Girardi L Bressan A Bertelli G Chiosi C 2000 Evolutionary tracks and isochrones for low and intermediate mass stars From 0 15 to 7 M and from Z 0 0004 to 0 03 Astronomy and Astrophysics Supplement Series 141 3 371 383 arXiv astro ph 9910164 Bibcode 2000A amp AS 141 371G doi 10 1051 aas 2000126 S2CID 14566232 External links editPost main sequence evolution through helium burning Long period variables period luminosity relations and classification in the Gaia Mission Retrieved from https en wikipedia org w index php title Red giant branch amp oldid 1186037951, wikipedia, wiki, book, books, library,

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