Misplaced Pages

Red giant: Difference between revisions

Article snapshot taken from Wikipedia with creative commons attribution-sharealike license. Give it a read and then ask your questions in the chat. We can research this topic together.
Browse history interactively← Previous editContent deleted Content addedVisualWikitext
Revision as of 21:59, 21 March 2024 edit132.181.229.175 (talk) Red-giant branchTag: Visual edit← Previous edit Latest revision as of 07:12, 21 November 2024 edit undoGerhardNel29 (talk | contribs)21 editsm the clarity improved a bitTags: Visual edit Mobile edit Mobile web edit Newcomer task Newcomer task: update 
(25 intermediate revisions by 19 users not shown)
Line 1: Line 1:
{{short description|Type of large cool star that has exhausted its core hydrogen}} {{short description|Type of large cool star}}
{{other uses}} {{other uses}}
{{For-multi|the very-high-mass stars which usually produce a supernova|red supergiant|the small dim stars|Red dwarf}}
{{Star nav}} {{Star nav}}
] simulations of a red giant, with giant convection cells and puffy surface]]
A '''red giant''' is a luminous ] of low or intermediate mass (roughly 0.3–8 ]es ({{Solar mass|link=y}})) in a late phase of ]. The outer ] is inflated and tenuous, making the radius large and the surface temperature around {{convert|5000|K|C F|sigfig=2}} or lower. The appearance of the red giant is from yellow-white to reddish-orange, including the ] K and M, sometimes G, but also ] and most ]s.

A '''red giant''' is a luminous ] of low or intermediate mass (roughly 0.3–8 ]es ({{Solar mass|link=y}})) in a late phase of ]. The ] is inflated and tenuous, making the radius large and the surface temperature around {{convert|5000|K|C F|sigfig=2|abbr=~|lk=in}} or lower. The appearance of the red giant is from yellow-white to reddish-orange, including the ] K and M, sometimes G, but also ] and most ]s.


Red giants vary in the way by which they generate energy: Red giants vary in the way by which they generate energy:


* most common red giants are stars on the ] (RGB) that are still ] into helium in a shell surrounding an inert helium core * most common red giants are stars on the ] (RGB) that are still ] into helium in a shell surrounding an inert helium core
* ] stars in the cool half of the ], fusing helium into carbon in their cores via the ] * ] stars in the cool half of the ], fusing helium into carbon in their cores via the ]
* ] (AGB) stars with a helium burning shell outside a degenerate carbon–oxygen core, and a hydrogen-burning shell just beyond that. * ] (AGB) stars with a helium burning shell outside a degenerate carbon–oxygen core, and a hydrogen-burning shell just beyond that.


Many of the well-known bright stars are red giants because they are luminous and moderately common. The K0 RGB star ] is 36 ]s away, and ] is the nearest M-class giant at 88 light-years' distance. Many of the ] are red giants because they are luminous and moderately common. The K0 RGB star ] is 36 ]s away, and ] is the nearest M-class giant at 88 light-years' distance.


A red giant will usually produce a ] and become a ] at the end of its life. A red giant will usually produce a ] and become a ] at the end of its life.


==Characteristics== ==Characteristics==
] ]
A red giant is a star that has exhausted the supply of hydrogen in its core and has begun ] of hydrogen in a shell surrounding the core. They have radii tens to hundreds of times larger than that of the ]. However, their outer envelope is lower in temperature, giving them a yellowish-orange hue. Despite the lower energy density of their envelope, red giants are many times more luminous than the Sun because of their great size. Red-giant-branch stars have luminosities up to nearly three thousand times that of the Sun ({{Solar luminosity|link=y}}), spectral types of K or M, have surface temperatures of 3,000–4,000 K, and radii up to about 200 times the Sun ({{Solar radius|link=y}}). Stars on the horizontal branch are hotter, with only a small range of luminosities around {{solar luminosity|75}}. Asymptotic-giant-branch stars range from similar luminosities as the brighter stars of the red-giant branch, up to several times more luminous at the end of the thermal pulsing phase. A red giant is a star that has exhausted the supply of hydrogen in its core and has begun ] of hydrogen in a shell surrounding the core. They have radii tens to hundreds of times larger than ]. However, their outer envelope is lower in temperature, giving them a yellowish-orange hue. Despite the lower energy density of their envelope, red giants are many times more luminous than the Sun because of their great size. Red-giant-branch stars have luminosities up to nearly three thousand times that of the Sun ({{Solar luminosity|link=y}}); spectral types of K or M have surface temperatures of {{val|3000|–|4000|ul=K|fmt=commas}} (compared with the ] temperature of nearly {{val|6000|u=K|fmt=commas}}) and radii up to about 200 times the Sun ({{Solar radius|link=y}}). Stars on the ] are hotter, with only a small range of luminosities around {{solar luminosity|75}}. ] stars range from similar luminosities as the brighter stars of the red-giant branch, up to several times more luminous at the end of the thermal pulsing phase.


Among the asymptotic-giant-branch stars belong the carbon stars of type C-N and late C-R, produced when carbon and other elements are convected to the surface in what is called a ].<ref name=boothroyd>{{Cite journal | last1 = Boothroyd | first1 = A. I. | last2 = Sackmann | first2 = I. -J. | doi = 10.1086/306546 | title = The CNO Isotopes: Deep Circulation in Red Giants and First and Second Dredge-up | journal = The Astrophysical Journal | volume = 510 | pages = 232–250 | year = 1999 | issue = 1 |bibcode = 1999ApJ...510..232B | arxiv = astro-ph/9512121 | s2cid = 561413 }}</ref> The first dredge-up occurs during hydrogen shell burning on the red-giant branch, but does not produce a large carbon abundance at the surface. The second, and sometimes third, dredge up occurs during helium shell burning on the asymptotic-giant branch and convects carbon to the surface in sufficiently massive stars. Among the asymptotic-giant-branch stars belong the ] of type C-N and late C-R, produced when carbon and other elements are convected to the surface in what is called a ].<ref name=boothroyd>{{Cite journal | last1 = Boothroyd | first1 = A. I. | last2 = Sackmann | first2 = I. -J. | doi = 10.1086/306546 | title = The CNO Isotopes: Deep Circulation in Red Giants and First and Second Dredge-up | journal = ] | volume = 510 | pages = 232–250 | year = 1999 | issue = 1 |bibcode = 1999ApJ...510..232B | arxiv = astro-ph/9512121 | s2cid = 561413 }}</ref> The first dredge-up occurs during hydrogen shell burning on the red-giant branch, but does not produce a large carbon abundance at the surface. The second, and sometimes third, dredge-up occurs during helium shell burning on the asymptotic-giant branch and convects carbon to the surface in sufficiently massive stars.


The stellar limb of a red giant is not sharply defined, contrary to their depiction in many illustrations. Rather, due to the very low mass density of the envelope, such stars lack a well-defined ], and the body of the star gradually transitions into a ']'.<ref name=suzuki>{{cite journal|bibcode=2007ApJ...659.1592S|arxiv=astro-ph/0608195|title=Structured Red Giant Winds with Magnetized Hot Bubbles and the Corona/Cool Wind Dividing Line|journal=The Astrophysical Journal|volume=659|issue=2|pages=1592–1610|last1=Suzuki|first1=Takeru K.|year=2007|doi=10.1086/512600|s2cid=13957448}}</ref> The coolest red giants have complex spectra, with molecular lines, emission features, and sometimes masers, particularly from thermally pulsing AGB stars.<ref name=habing>{{cite journal|bibcode=2003agbs.conf.....H|title=Asymptotic giant branch stars|journal=Asymptotic Giant Branch Stars|last1=Habing|first1=Harm J.|last2=Olofsson|first2=Hans|year=2003}}</ref> Observations have also provided evidence of a hot chromosphere above the photosphere of red giants,<ref>{{Cite book|last=Deutsch|first=A. J.|chapter=Chromospheric Activity in Red Giants, and Related Phenomena |date=1970|title=Ultraviolet Stellar Spectra and Related Ground-Based Observations|bibcode=1970IAUS...36..199D|volume=36|pages=199–208|doi=10.1007/978-94-010-3293-3_33|isbn=978-94-010-3295-7}}</ref><ref>{{Cite journal|last1=Vlemmings|first1=Wouter|last2=Khouri|first2=Theo|last3=O’Gorman|first3=Eamon|last4=De Beck|first4=Elvire|last5=Humphreys|first5=Elizabeth|last6=Lankhaar|first6=Boy|last7=Maercker|first7=Matthias|last8=Olofsson|first8=Hans|last9=Ramstedt|first9=Sofia|last10=Tafoya|first10=Daniel|last11=Takigawa|first11=Aki|date=December 2017|title=The shock-heated atmosphere of an asymptotic giant branch star resolved by ALMA|journal=Nature Astronomy|language=en|volume=1|issue=12|pages=848–853|doi=10.1038/s41550-017-0288-9|arxiv=1711.01153|bibcode=2017NatAs...1..848V|s2cid=119393687|issn=2397-3366}}</ref><ref>{{Cite journal|last1=O’Gorman|first1=E.|last2=Harper|first2=G. M.|last3=Ohnaka|first3=K.|last4=Feeney-Johansson|first4=A.|last5=Wilkeneit-Braun|first5=K.|last6=Brown|first6=A.|last7=Guinan|first7=E. F.|last8=Lim|first8=J.|last9=Richards|first9=A. M. S.|last10=Ryde|first10=N.|last11=Vlemmings|first11=W. H. T.|date=June 2020|title=ALMA and VLA reveal the lukewarm chromospheres of the nearby red supergiants Antares and Betelgeuse|journal=Astronomy & Astrophysics|volume=638|pages=A65|doi=10.1051/0004-6361/202037756|arxiv=2006.08023|bibcode=2020A&A...638A..65O|s2cid=219484950|issn=0004-6361}}</ref> where investigating the heating mechanisms for the chromospheres to form requires 3D simulations of red giants.<ref>{{Cite journal|last1=Wedemeyer|first1=Sven|last2=Kučinskas|first2=Arūnas|last3=Klevas|first3=Jonas|last4=Ludwig|first4=Hans-Günter|date=2017-10-01|title=Three-dimensional hydrodynamical CO5BOLD model atmospheres of red giant stars - VI. First chromosphere model of a late-type giant|journal=Astronomy & Astrophysics|language=en|volume=606|pages=A26|doi=10.1051/0004-6361/201730405|arxiv=1705.09641|bibcode=2017A&A...606A..26W|s2cid=119510487|issn=0004-6361}}</ref> The stellar limb of a red giant is not sharply defined, contrary to their depiction in many illustrations. Rather, due to the very low mass density of the envelope, such stars lack a well-defined ], and the body of the star gradually transitions into a ']'.<ref name=suzuki>{{cite journal|bibcode=2007ApJ...659.1592S|arxiv=astro-ph/0608195|title=Structured Red Giant Winds with Magnetized Hot Bubbles and the Corona/Cool Wind Dividing Line|journal=The Astrophysical Journal|volume=659|issue=2|pages=1592–1610|last1=Suzuki|first1=Takeru K.|year=2007|doi=10.1086/512600|s2cid=13957448}}</ref> The coolest red giants have complex spectra, with ], emission features, and sometimes ], particularly from thermally pulsing AGB stars.<ref name=habing>{{cite journal|bibcode=2003agbs.conf.....H|title=Asymptotic giant branch stars|journal=Asymptotic Giant Branch Stars|last1=Habing|first1=Harm J.|last2=Olofsson|first2=Hans|year=2003}}</ref> Observations have also provided evidence of a hot ] above the photosphere of red giants,<ref>{{Cite book|last=Deutsch|first=A. J.|chapter=Chromospheric Activity in Red Giants, and Related Phenomena |date=1970|title=Ultraviolet Stellar Spectra and Related Ground-Based Observations|bibcode=1970IAUS...36..199D|volume=36|pages=199–208|doi=10.1007/978-94-010-3293-3_33|isbn=978-94-010-3295-7}}</ref><ref>{{Cite journal|last1=Vlemmings|first1=Wouter|last2=Khouri|first2=Theo|last3=O’Gorman|first3=Eamon|last4=De Beck|first4=Elvire|last5=Humphreys|first5=Elizabeth|last6=Lankhaar|first6=Boy|last7=Maercker|first7=Matthias|last8=Olofsson|first8=Hans|last9=Ramstedt|first9=Sofia|last10=Tafoya|first10=Daniel|last11=Takigawa|first11=Aki|date=December 2017|title=The shock-heated atmosphere of an asymptotic giant branch star resolved by ALMA|journal=]|language=en|volume=1|issue=12|pages=848–853|doi=10.1038/s41550-017-0288-9|arxiv=1711.01153|bibcode=2017NatAs...1..848V|s2cid=119393687|issn=2397-3366}}</ref><ref>{{Cite journal|last1=O’Gorman|first1=E.|last2=Harper|first2=G. M.|last3=Ohnaka|first3=K.|last4=Feeney-Johansson|first4=A.|last5=Wilkeneit-Braun|first5=K.|last6=Brown|first6=A.|last7=Guinan|first7=E. F.|last8=Lim|first8=J.|last9=Richards|first9=A. M. S.|last10=Ryde|first10=N.|last11=Vlemmings|first11=W. H. T.|date=June 2020|title=ALMA and VLA reveal the lukewarm chromospheres of the nearby red supergiants Antares and Betelgeuse|journal=]|volume=638|pages=A65|doi=10.1051/0004-6361/202037756|arxiv=2006.08023|bibcode=2020A&A...638A..65O|s2cid=219484950|issn=0004-6361}}</ref> where investigating the heating mechanisms for the chromospheres to form requires 3D simulations of red giants.<ref>{{Cite journal|last1=Wedemeyer|first1=Sven|last2=Kučinskas|first2=Arūnas|last3=Klevas|first3=Jonas|last4=Ludwig|first4=Hans-Günter|date=2017-10-01|title=Three-dimensional hydrodynamical CO5BOLD model atmospheres of red giant stars - VI. First chromosphere model of a late-type giant|journal=Astronomy & Astrophysics|language=en|volume=606|pages=A26|doi=10.1051/0004-6361/201730405|arxiv=1705.09641|bibcode=2017A&A...606A..26W|s2cid=119510487|issn=0004-6361}}</ref>


Another noteworthy feature of red giants is that, unlike Sun-like stars whose photospheres have a large number of small convection cells (]), red-giant photospheres, as well as those of ]s, have just a few large cells, the features of which cause the ] so common on both types of stars.<ref name=Schwarzschild> Another noteworthy feature of red giants is that, unlike Sun-like stars whose photospheres have a large number of small convection cells (]), red-giant photospheres, as well as those of ]s, have just a few large cells, the features of which cause the ] so common on both types of stars.<ref name=Schwarzschild>
Line 38: Line 41:
==Evolution== ==Evolution==
{{Main|Stellar evolution#Mid-sized stars}} {{Main|Stellar evolution#Mid-sized stars}}
]-like star, from its ] on the ''left'' side of the frame to its ] into a red giant on the ''right'' after billions of years]] ], from its ] on the ''left'' side of the frame to its ] into a red giant on the ''right'' after billions of years]]
Red giants are evolved from ] stars with masses in the range from about {{Solar mass|0.3|link=y}} to around {{Solar mass|8}}.<ref name=endms/> When a star initially ] from a collapsing ] in the ], it contains primarily hydrogen and helium, with trace amounts of "]" (in stellar structure, this simply refers to ''any'' element that is not hydrogen or helium i.e. ] greater than 2). These elements are all uniformly mixed throughout the star. The star reaches the main sequence when the core reaches a temperature high enough to begin ] (a few million kelvin) and establishes ]. Over its main sequence life, the star slowly converts the hydrogen in the core into helium; its main-sequence life ends when nearly all the hydrogen in the core has been fused. For the ], the main-sequence lifetime is approximately 10&nbsp;billion years. More-massive stars burn disproportionately faster and so have a shorter lifetime than less massive stars.<ref name=zeilik>{{cite book | last=Zeilik | first=Michael A. |author2=Gregory, Stephan A. | title=Introductory Astronomy & Astrophysics | edition=4th | date=1998 | publisher=Saunders College Publishing | isbn=0-03-006228-4 | pages=321–322 }}</ref> Red giants are evolved from ] stars with masses in the range from about {{Solar mass|0.3|link=y}} to around {{Solar mass|8}}.<ref name=endms/> When a star initially ] from a collapsing ] in the ], it contains primarily hydrogen and helium, with trace amounts of "]" (in astrophysics, this refers to all elements heavier than hydrogen and helium). These elements are all uniformly mixed throughout the star. The star "enters" the main sequence when ] reaches a temperature (several million ]) high enough to begin fusing ] (the predominant isotope), and establishes ]. (In astrophysics, stellar fusion is often referred to as "burning", with hydrogen fusion sometimes termed "]".) Over its main sequence life, the star slowly fuses the hydrogen in the core into helium; its main-sequence life ends when nearly all the hydrogen in the core has been fused. For the Sun, the main-sequence lifetime is approximately 10&nbsp;billion years. More massive stars burn disproportionately faster and so have a shorter lifetime than less massive stars.<ref name=zeilik>{{cite book | last=Zeilik | first=Michael A. |author2=Gregory, Stephan A. | title=Introductory Astronomy & Astrophysics | edition=4th | date=1998 | publisher=Saunders College Publishing | isbn=0-03-006228-4 | pages=321–322 }}</ref>


When the star exhausts the hydrogen fuel in its core, nuclear reactions can no longer continue at the core and so the core begins to contract due to the diminishing force of the fusion, which used to push against gravity, and results in the core heating up. The increased temperature of the core causes hydrogen in a shell around the core to be burned and the star to expand.<ref name="Science Mission Directorate 2012 n322">{{cite web | title=Stars | website=Science Mission Directorate | date=2012-03-16 | url=https://science.nasa.gov/astrophysics/focus-areas/how-do-stars-form-and-evolve#:~:text=Hydrogen%20is%20still%20available%20outside,star%20into%20a%20red%20giant. | access-date=2023-08-29}}</ref> The hydrogen-burning shell results in a situation that has been described as the ''mirror principle''; when the core within the shell contracts, the layers of the star outside the shell must expand. The detailed physical processes that cause this are complex. Still, the behavior is necessary to satisfy simultaneous conservation of ] and ] in a star with the shell structure. The core contracts and heats up due to the lack of fusion, and so the outer layers of the star expand greatly, absorbing most of the extra energy from shell fusion. This process of cooling and expanding is the ] star. When the envelope of the star cools sufficiently it becomes convective, the star stops expanding, its luminosity starts to increase, and the star is ascending the ] of the ].<ref name=zeilik/><ref>{{cite book|author1=Tiago L. Campante|author2=Nuno C. Santos|author3=Mário J. P. F. G. Monteiro|title=Asteroseismology and Exoplanets: Listening to the Stars and Searching for New Worlds: IVth Azores International Advanced School in Space Sciences|url=https://books.google.com/books?id=keM8DwAAQBAJ&pg=PA99|date=3 November 2017|publisher=Springer|isbn=978-3-319-59315-9|pages=99–}}</ref> When the star has mostly exhausted the hydrogen fuel in its core, the core's rate of nuclear reactions declines, and thus so do the ] and ] the core generates, which are what support the star against ]. The star further contracts, increasing the pressures and thus temperatures inside the star (as described by the ]). Eventually a "shell" layer around the core reaches temperatures sufficient to fuse hydrogen and thus generate its own radiation and thermal pressure, which "re-inflates" the star's outer layers and causes them to expand.<ref name="Science Mission Directorate 2012 n322">{{cite web | title=Stars | website=] Science Mission Directorate | date=2012-03-16 | url=https://science.nasa.gov/astrophysics/focus-areas/how-do-stars-form-and-evolve#:~:text=Hydrogen%20is%20still%20available%20outside,star%20into%20a%20red%20giant. | access-date=2023-08-29}}</ref> The hydrogen-burning shell results in a situation that has been described as the ''mirror principle'': when the core within the shell contracts, the layers of the star outside the shell must expand. The detailed physical processes that cause this are complex. Still, the behavior is necessary to satisfy simultaneous conservation of ] and ] in a star with the shell structure. The core contracts and heats up due to the lack of fusion, and so the outer layers of the star expand greatly, absorbing most of the extra energy from shell fusion. This process of cooling and expanding is the ] stage. When the envelope of the star cools sufficiently it becomes ], the star stops expanding, its ] starts to increase, and the star is ascending the ] of the ].<ref name=zeilik/><ref>{{cite book|author1=Tiago L. Campante|author2=Nuno C. Santos|author3=Mário J. P. F. G. Monteiro|title=Asteroseismology and Exoplanets: Listening to the Stars and Searching for New Worlds: IVth Azores International Advanced School in Space Sciences|url=https://books.google.com/books?id=keM8DwAAQBAJ&pg=PA99|date=3 November 2017|publisher=Springer|isbn=978-3-319-59315-9|pages=99–}}</ref>


] is an old star, already shedding its outer layers into space]]
] is an old star, already shedding its outer layers into space]]
The evolutionary path the star takes as it moves along the red-giant branch depends on the mass of the star. For the Sun and stars of less than about {{Solar mass|2}}<ref name=fagotto>{{cite journal|bibcode=1994A&AS..105...29F|title=Evolutionary sequences of stellar models with new radiative opacities. IV. Z=0.004 and Z=0.008|journal=Astronomy and Astrophysics Supplement Series |volume=105|last1=Fagotto|first1=F.|last2=Bressan|first2=A.|last3=Bertelli|first3=G.|last4=Chiosi|first4=C.|year=1994|pages = 29}}</ref> the core will become dense enough that electron ] will prevent it from collapsing further. Once the core is ], it will continue to heat until it reaches a temperature of roughly 10<sup>8</sup>&nbsp;K, hot enough to begin fusing helium to carbon via the ]. Once the degenerate core reaches this temperature, the entire core will begin helium fusion nearly simultaneously in a so-called ]. In more-massive stars, the collapsing core will reach 10<sup>8</sup>&nbsp;K before it is dense enough to be degenerate, so helium fusion will begin much more smoothly, and produce no helium flash.<ref name=zeilik/> The core helium fusing phase of a star's life is called the ] in metal-poor stars, so named because these stars lie on a nearly horizontal line in the H–R diagram of many star clusters. Metal-rich helium-fusing stars instead lie on the so-called ] in the H–R diagram.<ref name=alves1999>{{cite journal|bibcode=1999ApJ...511..225A|arxiv=astro-ph/9808253|title=The Age-dependent Luminosities of the Red Giant Branch Bump, Asymptotic Giant Branch Bump, and Horizontal Branch Red Clump|journal=The Astrophysical Journal|volume=511|pages=225–234|last1=Alves|first1=David R.|last2=Sarajedini|first2=Ata|year=1999|issue=1|doi=10.1086/306655|s2cid=18834541}}</ref> The evolutionary path the star takes as it moves along the red-giant branch depends on the mass of the star. For the Sun and stars of less than about {{Solar mass|2}}<ref name=fagotto>{{cite journal|bibcode=1994A&AS..105...29F|title=Evolutionary sequences of stellar models with new radiative opacities. IV. Z=0.004 and Z=0.008|journal=Astronomy and Astrophysics Supplement Series |volume=105|last1=Fagotto|first1=F.|last2=Bressan|first2=A.|last3=Bertelli|first3=G.|last4=Chiosi|first4=C.|year=1994|pages = 29}}</ref> the core will become dense enough that ] will prevent it from collapsing further. Once the core is ], it will continue to heat until it reaches a temperature of roughly {{val|1e8|u=K}}, hot enough to begin fusing helium to carbon via the ]. Once the degenerate core reaches this temperature, the entire core will begin helium fusion nearly simultaneously in a so-called ]. In more-massive stars, the collapsing core will reach these temperatures before it is dense enough to be degenerate, so helium fusion will begin much more smoothly, and produce no helium flash.<ref name=zeilik/> The core helium fusing phase of a star's life is called the ] in ], so named because these stars lie on a nearly horizontal line in the H–R diagram of many star clusters. Metal-rich helium-fusing stars instead lie on the so-called ] in the H–R diagram.<ref name=alves1999>{{cite journal|bibcode=1999ApJ...511..225A|arxiv=astro-ph/9808253|title=The Age-dependent Luminosities of the Red Giant Branch Bump, Asymptotic Giant Branch Bump, and Horizontal Branch Red Clump|journal=The Astrophysical Journal|volume=511|pages=225–234|last1=Alves|first1=David R.|last2=Sarajedini|first2=Ata|year=1999|issue=1|doi=10.1086/306655|s2cid=18834541}}</ref>


An analogous process occurs when the central helium is exhausted and the star collapses once again, causing helium in a shell to begin fusing. At the same time, hydrogen may begin fusion in a shell just outside the burning helium shell. This puts the star onto the ], a second red-giant phase.<ref name=sackmann>{{Cite journal | last1 = Sackmann | first1 = I. -J. | last2 = Boothroyd | first2 = A. I. | last3 = Kraemer | first3 = K. E. | title = Our Sun. III. Present and Future | doi = 10.1086/173407 | journal = The Astrophysical Journal | volume = 418 | pages = 457 | year = 1993 |bibcode = 1993ApJ...418..457S | doi-access = free }}</ref> The helium fusion results in the build-up of a carbon–oxygen core. A star below about {{Solar mass|8}} will never start fusion in its degenerate carbon–oxygen core.<ref name=fagotto/> Instead, at the end of the asymptotic-giant-branch phase the star will eject its outer layers, forming a ] with the core of the star exposed, ultimately becoming a ]. The ejection of the outer mass and the creation of a planetary nebula finally ends the red-giant phase of the star's evolution.<ref name=zeilik/> The red-giant phase typically lasts only around a billion years in total for a solar mass star, almost all of which is spent on the red-giant branch. The horizontal-branch and asymptotic-giant-branch phases proceed tens of times faster. An analogous process occurs when the core helium is exhausted, and the star collapses once again, causing helium in a shell to begin fusing. At the same time, hydrogen may begin fusion in a shell just outside the burning helium shell. This puts the star onto the ], a second red-giant phase.<ref name=sackmann>{{Cite journal | last1 = Sackmann | first1 = I. -J. | last2 = Boothroyd | first2 = A. I. | last3 = Kraemer | first3 = K. E. | title = Our Sun. III. Present and Future | doi = 10.1086/173407 | journal = The Astrophysical Journal | volume = 418 | pages = 457 | year = 1993 |bibcode = 1993ApJ...418..457S | doi-access = free }}</ref> The helium fusion results in the build-up of a carbon–oxygen core. A star below about {{Solar mass|8}} will never start fusion in its degenerate carbon–oxygen core.<ref name=fagotto/> Instead, at the end of the asymptotic-giant-branch phase the star will eject its outer layers, forming a ] with the core of the star exposed, ultimately becoming a ]. The ejection of the outer mass and the creation of a planetary nebula finally ends the red-giant phase of the star's evolution.<ref name=zeilik/> The red-giant phase typically lasts only around a billion years in total for a solar mass star, almost all of which is spent on the red-giant branch. The horizontal-branch and asymptotic-giant-branch phases proceed tens of times faster.


If the star has about 0.2 to {{Solar mass|0.5}},<ref name=fagotto/> it is massive enough to become a red giant but does not have enough mass to initiate the fusion of helium.<ref name=endms/> These "intermediate" stars cool somewhat and increase their luminosity but never achieve the tip of the red-giant branch and helium core flash. When the ascent of the red-giant branch ends they puff off their outer layers much like a post-asymptotic-giant-branch star and then become a white dwarf. If the star has about 0.2 to {{Solar mass|0.5}},<ref name=fagotto/> it is massive enough to become a red giant but does not have enough mass to initiate the fusion of helium.<ref name=endms/> These "intermediate" stars cool somewhat and increase their luminosity but never achieve the tip of the red-giant branch and helium core flash. When the ascent of the red-giant branch ends they puff off their outer layers much like a post-asymptotic-giant-branch star and then become a white dwarf.


===Stars that do not become red giants=== ===Stars that do not become red giants===
Very-low-mass stars are ]<ref name=aaa496_3_787>{{cite journal |bibcode=2009A&A...496..787R |arxiv=0901.1659 |title=On the magnetic topology of partially and fully convective stars |journal=Astronomy and Astrophysics |volume=496 |issue=3 |pages=787 |last1=Reiners |first1=Ansgar |last2=Basri |first2=Gibor |year=2009 |doi=10.1051/0004-6361:200811450 |s2cid=15159121 }}</ref><ref>{{cite web |last=Brainerd |first=Jerome James |date=2005-02-16 |title=Main-Sequence Stars |url=http://www.astrophysicsspectator.com/topics/stars/MainSequence.html |archive-url=https://web.archive.org/web/20061206065847/http://www.astrophysicsspectator.com/topics/stars/MainSequence.html |archive-date=2006-12-06 |access-date=2006-12-29 |work=Stars |publisher=The Astrophysics Spectator}}</ref> and may continue to fuse hydrogen into helium for up to a ]<ref>{{cite web

Very-low-mass stars are ]<ref name=aaa496_3_787>{{cite journal |bibcode=2009A&A...496..787R |arxiv=0901.1659 |title=On the magnetic topology of partially and fully convective stars |journal=Astronomy and Astrophysics |volume=496 |issue=3 |pages=787 |last1=Reiners |first1=Ansgar |last2=Basri |first2=Gibor |year=2009 |doi=10.1051/0004-6361:200811450 |s2cid=15159121 }}</ref><ref>{{cite web
| last=Brainerd | first=Jerome James
| title=Main-Sequence Stars | work=Stars
| publisher=The Astrophysics Spectator | date=2005-02-16
| url=http://www.astrophysicsspectator.com/topics/stars/MainSequence.html
| access-date=2006-12-29 }}</ref> and may continue to fuse hydrogen into helium for up to a trillion years<ref>{{cite web
| last=Richmond | first=Michael | last=Richmond | first=Michael
| title=Late stages of evolution for low-mass stars | title=Late stages of evolution for low-mass stars
Line 63: Line 60:
| access-date=2006-12-29 }}</ref> until only a small fraction of the entire star is hydrogen. Luminosity and temperature steadily increase during this time, just as for more-massive main-sequence stars, but the length of time involved means that the temperature eventually increases by about 50% and the luminosity by around 10 times. Eventually the level of helium increases to the point where the star ceases to be fully convective and the remaining hydrogen locked in the core is consumed in only a few billion more years. Depending on mass, the temperature and luminosity continue to increase for a time during hydrogen shell burning, the star can become hotter than the Sun and tens of times more luminous than when it formed although still not as luminous as the Sun. After some billions more years, they start to become less luminous and cooler even though hydrogen shell burning continues. These become cool helium white dwarfs.<ref name=endms>{{Cite journal | last1 = Laughlin | first1 = G. | last2 = Bodenheimer | first2 = P. | last3 = Adams | first3 = F. C. | title = The End of the Main Sequence | doi = 10.1086/304125 | journal = The Astrophysical Journal | volume = 482 | pages = 420–432 | year = 1997 | issue = 1 |bibcode = 1997ApJ...482..420L | doi-access = free }}</ref> | access-date=2006-12-29 }}</ref> until only a small fraction of the entire star is hydrogen. Luminosity and temperature steadily increase during this time, just as for more-massive main-sequence stars, but the length of time involved means that the temperature eventually increases by about 50% and the luminosity by around 10 times. Eventually the level of helium increases to the point where the star ceases to be fully convective and the remaining hydrogen locked in the core is consumed in only a few billion more years. Depending on mass, the temperature and luminosity continue to increase for a time during hydrogen shell burning, the star can become hotter than the Sun and tens of times more luminous than when it formed although still not as luminous as the Sun. After some billions more years, they start to become less luminous and cooler even though hydrogen shell burning continues. These become cool helium white dwarfs.<ref name=endms>{{Cite journal | last1 = Laughlin | first1 = G. | last2 = Bodenheimer | first2 = P. | last3 = Adams | first3 = F. C. | title = The End of the Main Sequence | doi = 10.1086/304125 | journal = The Astrophysical Journal | volume = 482 | pages = 420–432 | year = 1997 | issue = 1 |bibcode = 1997ApJ...482..420L | doi-access = free }}</ref>


Very-high-mass stars develop into ]s that follow an ] that takes them back and forth horizontally over the H–R diagram, at the right end constituting ]s. These usually end their life as a type II ]. The most massive stars can become ]s without becoming giants or supergiants at all.<ref name="Crowther 2007">{{Cite journal |last=Crowther |first=P. A. |date=2007 |title=Physical Properties of Wolf-Rayet Stars |journal=Annual Review of Astronomy and Astrophysics |volume=45 |issue= 1|pages=177–219 |doi=10.1146/annurev.astro.45.051806.110615 |bibcode=2007ARA&A..45..177C|arxiv = astro-ph/0610356 |s2cid=1076292 }}</ref><ref>{{cite journal|version=v1|display-authors=4|author1=Georges Meynet|author2=Cyril Georgy|author3=Raphael Hirschi|author4=Andre Maeder|author5=Phil Massey|author6=Norbert Przybilla|author7=Fernanda Nieva|title=Red Supergiants, Luminous Blue Variables and Wolf-Rayet stars: The single massive star perspective |pages=266–278 |volume=80 |issue=39 |journal=Société Royale des Sciences de Liège, Bulletin (Proceedings of the 39th Liège Astrophysical Colloquium) |location=Liège |date=12–16 July 2010 |display-editors=4 |editor=G. Rauw |editor2=M. De Becker |editor3=Y. Nazé |editor4=J.-M. Vreux |editor5=P. Williams|arxiv=1101.5873|bibcode = 2011BSRSL..80..266M }}</ref> Very-high-mass stars develop into ]s that follow an ] that takes them back and forth horizontally over the H–R diagram, at the right end constituting ]s. These usually end their life as a ]. The most massive stars can become ]s without becoming giants or supergiants at all.<ref name="Crowther 2007">{{Cite journal |last=Crowther |first=P. A. |date=2007 |title=Physical Properties of Wolf-Rayet Stars |journal=Annual Review of Astronomy and Astrophysics |volume=45 |issue= 1|pages=177–219 |doi=10.1146/annurev.astro.45.051806.110615 |bibcode=2007ARA&A..45..177C|arxiv = astro-ph/0610356 |s2cid=1076292 }}</ref><ref>{{cite journal|version=v1|display-authors=4|author1=Georges Meynet|author2=Cyril Georgy|author3=Raphael Hirschi|author4=Andre Maeder|author5=Phil Massey|author6=Norbert Przybilla|author7=Fernanda Nieva|title=Red Supergiants, Luminous Blue Variables and Wolf-Rayet stars: The single massive star perspective |pages=266–278 |volume=80 |issue=39 |journal=], Bulletin (Proceedings of the 39th Liège Astrophysical Colloquium) |location=Liège |date=12–16 July 2010 |display-editors=4 |editor=G. Rauw |editor2=M. De Becker |editor3=Y. Nazé |editor4=J.-M. Vreux |editor5=P. Williams|arxiv=1101.5873|bibcode = 2011BSRSL..80..266M }}</ref>


==Planets== ==Planets==
Line 69: Line 66:


===Prospects for habitability=== ===Prospects for habitability===
Although traditionally it has been suggested the evolution of a star into a red giant will render its ], if present, uninhabitable, some research suggests that, during the evolution of a {{Solar mass|1}} star along the red-giant branch, it could harbor a ] for several billion years at 2 ]s (AU) out to around 100 million years at {{Val|9|u=AU}} out, giving perhaps enough time for life to develop on a suitable world. After the red-giant stage, there would for such a star be a habitable zone between {{Val|7|and|22|u=AU}} for an additional one billion years.<ref name="Lopez2005">{{cite journal

Although traditionally it has been suggested the evolution of a star into a red giant will render its ], if present, uninhabitable, some research suggests that, during the evolution of a {{Solar mass|1}} star along the red-giant branch, it could harbor a ] for several billion years at 2 ]s (AU) out to around 100 million years at 9 AU out, giving perhaps enough time for life to develop on a suitable world. After the red-giant stage, there would for such a star be a habitable zone between 7 and 22 AU for an additional one billion years.<ref name="Lopez2005">{{cite journal
| author=Lopez, Bruno | author=Lopez, Bruno
| author2=Schneider, Jean | author2=Schneider, Jean
Line 83: Line 79:
| doi=10.1086/430416|arxiv = astro-ph/0503520 | doi=10.1086/430416|arxiv = astro-ph/0503520
| s2cid=17075384 | s2cid=17075384
}}</ref> Later studies have refined this scenario, showing how for a {{Solar mass|1}} star the habitable zone lasts from 100 million years for a planet with an orbit similar to that of ] to 210 million years for one that orbits at ]'s distance to the Sun, the maximum time (370 million years) corresponding for planets orbiting at the distance of ]. However, planets orbiting a {{Solar mass|0.5}} star in equivalent orbits to those of Jupiter and Saturn would be in the habitable zone for 5.8 billion years and 2.1 billion years, respectively; for stars more massive than the Sun, the times are considerably shorter.<ref name="Ramses2016">{{cite journal }}</ref> Later studies have refined this scenario, showing how for a {{Solar mass|1}} star the habitable zone lasts from 100 million years for a planet with an orbit similar to that of ] to 210 million years for one that orbits at ] distance to the Sun, the maximum time (370 million years) corresponding for planets orbiting at the distance of ]. However, planets orbiting a {{Solar mass|0.5}} star in equivalent orbits to those of Jupiter and Saturn would be in the habitable zone for 5.8 billion years and 2.1 billion years, respectively; for stars more massive than the Sun, the times are considerably shorter.<ref name="Ramses2016">{{cite journal
| author=Ramirez, Ramses M. | author=Ramirez, Ramses M.
| author2=Kaltenegger, Lisa | author2=Kaltenegger, Lisa
Line 99: Line 95:


===Enlargement of planets=== ===Enlargement of planets===
As of 2023, several hundred ] have been discovered around giant stars.<ref>{{Cite web |title=Planetary Systems |url=https://exoplanetarchive.ipac.caltech.edu/cgi-bin/TblView/nph-tblView?app=ExoTbls&config=PS |access-date=2023-08-10 |website=exoplanetarchive.ipac.caltech.edu}}</ref> However, these giant planets are more massive than the giant planets found around solar-type stars. This could be because giant stars are more massive than the Sun (less massive stars will still be on the ] and will not have become giants yet) and more massive stars are expected to have more massive planets. However, the masses of the planets that have been found around giant stars do not correlate with the masses of the stars; therefore, the planets could be growing in mass during the stars' red giant phase. The growth in planet mass could be partly due to accretion from stellar wind, although a much larger effect would be ] overflow causing mass-transfer from the star to the planet when the giant expands out to the orbital distance of the planet.<ref name=jones>{{cite journal|bibcode=2014A&A...566A.113J|arxiv=1406.0884|title=The properties of planets around giant stars|journal=Astronomy & Astrophysics|volume=566|pages=A113|last1=Jones|first1=M. I.|last2=Jenkins|first2=J. S.|last3=Bluhm|first3=P.|last4=Rojo|first4=P.|last5=Melo|first5=C. H. F.|year=2014|doi=10.1051/0004-6361/201323345|s2cid=118396750}}</ref> (A similar process in ] is believed to be the cause of most ] and ].)

As of 2023, several hundred giant planets have been discovered around giant stars.<ref>{{Cite web |title=Planetary Systems |url=https://exoplanetarchive.ipac.caltech.edu/cgi-bin/TblView/nph-tblView?app=ExoTbls&config=PS |access-date=2023-08-10 |website=exoplanetarchive.ipac.caltech.edu}}</ref> However, these giant planets are more massive than the giant planets found around solar-type stars. This could be because giant stars are more massive than the Sun (less massive stars will still be on the ] and will not have become giants yet) and more massive stars are expected to have more massive planets. However, the masses of the planets that have been found around giant stars do not correlate with the masses of the stars; therefore, the planets could be growing in mass during the stars' red giant phase. The growth in planet mass could be partly due to accretion from stellar wind, although a much larger effect would be ] overflow causing mass-transfer from the star to the planet when the giant expands out to the orbital distance of the planet.<ref name=jones>{{cite journal|bibcode=2014A&A...566A.113J|arxiv=1406.0884|title=The properties of planets around giant stars|journal=Astronomy & Astrophysics|volume=566|pages=A113|last1=Jones|first1=M. I.|last2=Jenkins|first2=J. S.|last3=Bluhm|first3=P.|last4=Rojo|first4=P.|last5=Melo|first5=C. H. F.|year=2014|doi=10.1051/0004-6361/201323345|s2cid=118396750}}</ref>


==Examples== ==Examples==
Many of the well-known bright stars are red giants, because they are luminous and moderately common. The red-giant branch variable star ] is the nearest M-class giant star at 88 light-years.<ref name=ireland>{{cite journal | display-authors=1 |last1=Ireland | first1=M. J. | last2=Tuthill | first2=P. G. | last3=Bedding | first3=T. R. | last4=Robertson | first4=J. G. | last5=Jacob | first5=A. P. | title=Multiwavelength diameters of nearby Miras and semiregular variables | journal=Monthly Notices of the Royal Astronomical Society | volume=350 | issue=1 | pages=365–374 |date=May 2004 | doi=10.1111/j.1365-2966.2004.07651.x | bibcode=2004MNRAS.350..365I |arxiv = astro-ph/0402326 |s2cid=15830460 }}</ref> The K1.5 red-giant branch star ] is 36 light-years away.<ref name=abia>{{cite journal|bibcode=2012A&A...548A..55A|arxiv=1210.1160|title=Carbon and oxygen isotopic ratios in Arcturus and Aldebaran. Constraining the parameters for non-convective mixing on the red giant branch|journal=Astronomy & Astrophysics|volume=548|pages=A55|last1=Abia|first1=C.|last2=Palmerini|first2=S.|last3=Busso|first3=M.|last4=Cristallo|first4=S.|year=2012|doi=10.1051/0004-6361/201220148|s2cid=56386673}}</ref> Many of the ] are red giants, because they are luminous and moderately common. The red-giant branch variable star ] is the nearest M-class giant star at 88 light-years.<ref name=ireland>{{cite journal | display-authors=1 |last1=Ireland | first1=M. J. | last2=Tuthill | first2=P. G. | last3=Bedding | first3=T. R. | last4=Robertson | first4=J. G. | last5=Jacob | first5=A. P. | title=Multiwavelength diameters of nearby Miras and semiregular variables | journal=] | volume=350 | issue=1 | pages=365–374 |date=May 2004 | doi=10.1111/j.1365-2966.2004.07651.x |doi-access=free | bibcode=2004MNRAS.350..365I |arxiv = astro-ph/0402326 |s2cid=15830460 }}</ref> The K1.5 red-giant branch star ] is 36 light-years away.<ref name=abia>{{cite journal|bibcode=2012A&A...548A..55A|arxiv=1210.1160|title=Carbon and oxygen isotopic ratios in Arcturus and Aldebaran. Constraining the parameters for non-convective mixing on the red giant branch|journal=Astronomy & Astrophysics|volume=548|pages=A55|last1=Abia|first1=C.|last2=Palmerini|first2=S.|last3=Busso|first3=M.|last4=Cristallo|first4=S.|year=2012|doi=10.1051/0004-6361/201220148|s2cid=56386673}}</ref>


===Red-giant branch=== ===Red-giant branch===
* ] (α Tauri) * ] (α Tauri)
* ] (α Bootis) * ] (α Bootis)
* ]<ref name=":0">{{Cite journal |last1=Howes |first1=Louise M. |last2=Lindegren |first2=Lennart |last3=Feltzing |first3=Sofia |last4=Church |first4=Ross P. |last5=Bensby |first5=Thomas |date=February 2019 |title=Estimating stellar ages and metallicities from parallaxes and broadband photometry: successes and shortcomings |url=https://www.aanda.org/10.1051/0004-6361/201833280 |journal=Astronomy & Astrophysics |volume=622 |pages=A27 |doi=10.1051/0004-6361/201833280 |issn=0004-6361|arxiv=1804.08321 |bibcode=2019A&A...622A..27H }}</ref>
* ] (γ Crucis) * ] (γ Crucis)
* ]


===Red-clump giants=== ===Red-clump giants===
* ] (β Geminorum)<ref name=":0" />
* ] Aa (α Aurigae) * ] Aa (α Aurigae)
* ] (Schedar)
* ]
* ]<ref name=alves2000>{{cite journal|bibcode=2000ApJ...539..732A|arxiv=astro-ph/0003329|title=K-Band Calibration of the Red Clump Luminosity|journal=The Astrophysical Journal|volume=539|issue=2|pages=732–741|last1=Alves|first1=David R.|year=2000|doi=10.1086/309278|s2cid=16673121}}</ref>
* ]
* ]<ref name=alves2000>{{cite journal|bibcode=2000ApJ...539..732A|arxiv=astro-ph/0003329|title=K-Band Calibration of the Red Clump Luminosity|journal=The Astrophysical Journal|volume=539|issue=2|pages=732–741|last1=Alves|first1=David R.|year=2000|doi=10.1086/309278|s2cid=16673121}}</ref>


===Asymptotic giant branch=== ===Asymptotic giant branch===
* ] (Gorgonea Tertia)
* ] (ο Ceti) * ] (ο Ceti)
* ] * ]
* ] * ] (Rasalgethi)
* ]


=={{Anchor|The Sun as a red giant}}The Sun as a red giant== ==The Sun as a red giant<span class="anchor" id="The Sun as a red giant"></span>==
{{Main|End of the Sun}} {{Main|End of the Sun}}
The Sun will exit the ] in approximately 5 billion years and start to turn into a red giant.<ref>{{cite web |author1=Nola Taylor Redd |title=Red Giant Stars: Facts, Definition & the Future of the Sun |url=http://www.space.com/22471-red-giant-stars.html |website=space.com |access-date=20 February 2016}}</ref><ref name=schroder>{{Cite journal |last1=Schröder |first1=K.-P. |last2=Connon Smith |first2=R. |doi=10.1111/j.1365-2966.2008.13022.x |title=Distant future of the Sun and Earth revisited |journal=Monthly Notices of the Royal Astronomical Society |volume=386 |issue=1 |pages=155–163 |year=2008 |arxiv=0801.4031 |bibcode=2008MNRAS.386..155S|s2cid=10073988 }}</ref> As a red giant, the Sun will grow so large (over 200 times its present-day radius) (1 AU) that it will engulf ], ], and likely Earth. It will lose 38% of its mass growing, then will shrink into a ].<ref>{{cite news |last1=Siegel |first1=Ethan |title=Ask Ethan: Will The Earth Eventually Be Swallowed By The Sun? |url=https://www.forbes.com/sites/startswithabang/2020/02/08/ask-ethan-will-the-earth-eventually-be-swallowed-by-the-sun/ |access-date=12 March 2021 |work=Forbes |date=8 February 2020 |language=en}}</ref> The Sun will exit the ] in approximately 5 billion years and start to turn into a red giant.<ref>{{cite web |author1=Nola Taylor Redd |title=Red Giant Stars: Facts, Definition & the Future of the Sun |url=http://www.space.com/22471-red-giant-stars.html |website=space.com |access-date=20 February 2016}}</ref><ref name=schroder>{{Cite journal |last1=Schröder |first1=K.-P. |last2=Connon Smith |first2=R. |doi=10.1111/j.1365-2966.2008.13022.x |title=Distant future of the Sun and Earth revisited |journal=Monthly Notices of the Royal Astronomical Society |volume=386 |issue=1 |pages=155–163 |year=2008 |doi-access=free |arxiv=0801.4031 |bibcode=2008MNRAS.386..155S|s2cid=10073988 }}</ref> As a red giant, the Sun will grow so large (over 200 times its ]: {{approx|215|tilde=y}}{{nbsp}}{{Solar radius}}; {{Approx|{{Val|1|ul=AU}}|tilde=y}}) that it will engulf ], ], and likely Earth. It will lose 38% of its mass growing, then will die into a ].<ref>{{cite news |last1=Siegel |first1=Ethan |title=Ask Ethan: Will The Earth Eventually Be Swallowed By The Sun? |url=https://www.forbes.com/sites/startswithabang/2020/02/08/ask-ethan-will-the-earth-eventually-be-swallowed-by-the-sun/ |access-date=12 March 2021 |work=Forbes |date=8 February 2020 |language=en}}</ref>


{{clear}} {{clear}}
Line 139: Line 134:
{{Use dmy dates|date=July 2019}} {{Use dmy dates|date=July 2019}}


]
] ]
] ]
]

Latest revision as of 07:12, 21 November 2024

Type of large cool star For other uses, see Red giant (disambiguation). For the very-high-mass stars which usually produce a supernova, see red supergiant. For the small dim stars, see Red dwarf. Hertzsprung–Russell diagram Spectral type O B A F G K M L T Brown dwarfs White dwarfs Red dwarfs Subdwarfs Main sequence
("dwarfs")
Subgiants Giants Red giants Blue giants Bright giants Supergiants Red supergiant Hypergiants absolute
magni-
tude
(MV)
A spherical object, dimly red-to-black with highly complex and chaotic, randomly-oriented patterns of varying brightness on its surface, against a black background
Fluid dynamics simulations of a red giant, with giant convection cells and puffy surface

A red giant is a luminous giant star of low or intermediate mass (roughly 0.3–8 solar masses (M)) in a late phase of stellar evolution. The outer atmosphere is inflated and tenuous, making the radius large and the surface temperature around 5,000 K (4,700 °C; 8,500 °F) or lower. The appearance of the red giant is from yellow-white to reddish-orange, including the spectral types K and M, sometimes G, but also class S stars and most carbon stars.

Red giants vary in the way by which they generate energy:

Many of the well-known bright stars are red giants because they are luminous and moderately common. The K0 RGB star Arcturus is 36 light-years away, and Gacrux is the nearest M-class giant at 88 light-years' distance.

A red giant will usually produce a planetary nebula and become a white dwarf at the end of its life.

Characteristics

refer to text nearby and section "The Sun as a red giant"
An illustration comparing the structure of the Sun (left) and its possible future as a red giant (right; not to scale). The inset at the bottom right shows a size comparison.

A red giant is a star that has exhausted the supply of hydrogen in its core and has begun thermonuclear fusion of hydrogen in a shell surrounding the core. They have radii tens to hundreds of times larger than that of the Sun. However, their outer envelope is lower in temperature, giving them a yellowish-orange hue. Despite the lower energy density of their envelope, red giants are many times more luminous than the Sun because of their great size. Red-giant-branch stars have luminosities up to nearly three thousand times that of the Sun (L); spectral types of K or M have surface temperatures of 3,000–4,000 K (compared with the Sun's photosphere temperature of nearly 6,000 K) and radii up to about 200 times the Sun (R). Stars on the horizontal branch are hotter, with only a small range of luminosities around 75 L. Asymptotic-giant-branch stars range from similar luminosities as the brighter stars of the red-giant branch, up to several times more luminous at the end of the thermal pulsing phase.

Among the asymptotic-giant-branch stars belong the carbon stars of type C-N and late C-R, produced when carbon and other elements are convected to the surface in what is called a dredge-up. The first dredge-up occurs during hydrogen shell burning on the red-giant branch, but does not produce a large carbon abundance at the surface. The second, and sometimes third, dredge-up occurs during helium shell burning on the asymptotic-giant branch and convects carbon to the surface in sufficiently massive stars.

The stellar limb of a red giant is not sharply defined, contrary to their depiction in many illustrations. Rather, due to the very low mass density of the envelope, such stars lack a well-defined photosphere, and the body of the star gradually transitions into a 'corona'. The coolest red giants have complex spectra, with molecular lines, emission features, and sometimes masers, particularly from thermally pulsing AGB stars. Observations have also provided evidence of a hot chromosphere above the photosphere of red giants, where investigating the heating mechanisms for the chromospheres to form requires 3D simulations of red giants.

Another noteworthy feature of red giants is that, unlike Sun-like stars whose photospheres have a large number of small convection cells (solar granules), red-giant photospheres, as well as those of red supergiants, have just a few large cells, the features of which cause the variations of brightness so common on both types of stars.

Evolution

Main article: Stellar evolution § Mid-sized stars
refer to text
This image tracks the life of a Sun-like star, from its birth on the left side of the frame to its evolution into a red giant on the right after billions of years

Red giants are evolved from main-sequence stars with masses in the range from about 0.3 M to around 8 M. When a star initially forms from a collapsing molecular cloud in the interstellar medium, it contains primarily hydrogen and helium, with trace amounts of "metals" (in astrophysics, this refers to all elements heavier than hydrogen and helium). These elements are all uniformly mixed throughout the star. The star "enters" the main sequence when its core reaches a temperature (several million kelvins) high enough to begin fusing hydrogen-1 (the predominant isotope), and establishes hydrostatic equilibrium. (In astrophysics, stellar fusion is often referred to as "burning", with hydrogen fusion sometimes termed "hydrogen burning".) Over its main sequence life, the star slowly fuses the hydrogen in the core into helium; its main-sequence life ends when nearly all the hydrogen in the core has been fused. For the Sun, the main-sequence lifetime is approximately 10 billion years. More massive stars burn disproportionately faster and so have a shorter lifetime than less massive stars.

When the star has mostly exhausted the hydrogen fuel in its core, the core's rate of nuclear reactions declines, and thus so do the radiation and thermal pressure the core generates, which are what support the star against gravitational contraction. The star further contracts, increasing the pressures and thus temperatures inside the star (as described by the ideal gas law). Eventually a "shell" layer around the core reaches temperatures sufficient to fuse hydrogen and thus generate its own radiation and thermal pressure, which "re-inflates" the star's outer layers and causes them to expand. The hydrogen-burning shell results in a situation that has been described as the mirror principle: when the core within the shell contracts, the layers of the star outside the shell must expand. The detailed physical processes that cause this are complex. Still, the behavior is necessary to satisfy simultaneous conservation of gravitational and thermal energy in a star with the shell structure. The core contracts and heats up due to the lack of fusion, and so the outer layers of the star expand greatly, absorbing most of the extra energy from shell fusion. This process of cooling and expanding is the subgiant stage. When the envelope of the star cools sufficiently it becomes convective, the star stops expanding, its luminosity starts to increase, and the star is ascending the red-giant branch of the Hertzsprung–Russell (H–R) diagram.

Space telescope image of star Mira A, observed from Earth. A cloud of gas and dust is illuminated by a whitish light concentrated at center of image; some hints of blue and yellow are visible near the center. The clouds obscure direct view of the star, and are front- and backlit by its light depending on their orientations, with some of the thick dark clouds between the star and viewer standing out due to partially obscuring the light from the star. The image darkens rapidly towards its edges as the clouds absorb and scatter the light, first becoming increasingly dimmer and redder, and closer to the edges the image becomes more or less completely black.
Mira A is an old star, already shedding its outer layers into space

The evolutionary path the star takes as it moves along the red-giant branch depends on the mass of the star. For the Sun and stars of less than about 2 M the core will become dense enough that electron degeneracy pressure will prevent it from collapsing further. Once the core is degenerate, it will continue to heat until it reaches a temperature of roughly 1×10 K, hot enough to begin fusing helium to carbon via the triple-alpha process. Once the degenerate core reaches this temperature, the entire core will begin helium fusion nearly simultaneously in a so-called helium flash. In more-massive stars, the collapsing core will reach these temperatures before it is dense enough to be degenerate, so helium fusion will begin much more smoothly, and produce no helium flash. The core helium fusing phase of a star's life is called the horizontal branch in metal-poor stars, so named because these stars lie on a nearly horizontal line in the H–R diagram of many star clusters. Metal-rich helium-fusing stars instead lie on the so-called red clump in the H–R diagram.

An analogous process occurs when the core helium is exhausted, and the star collapses once again, causing helium in a shell to begin fusing. At the same time, hydrogen may begin fusion in a shell just outside the burning helium shell. This puts the star onto the asymptotic giant branch, a second red-giant phase. The helium fusion results in the build-up of a carbon–oxygen core. A star below about 8 M will never start fusion in its degenerate carbon–oxygen core. Instead, at the end of the asymptotic-giant-branch phase the star will eject its outer layers, forming a planetary nebula with the core of the star exposed, ultimately becoming a white dwarf. The ejection of the outer mass and the creation of a planetary nebula finally ends the red-giant phase of the star's evolution. The red-giant phase typically lasts only around a billion years in total for a solar mass star, almost all of which is spent on the red-giant branch. The horizontal-branch and asymptotic-giant-branch phases proceed tens of times faster.

If the star has about 0.2 to 0.5 M, it is massive enough to become a red giant but does not have enough mass to initiate the fusion of helium. These "intermediate" stars cool somewhat and increase their luminosity but never achieve the tip of the red-giant branch and helium core flash. When the ascent of the red-giant branch ends they puff off their outer layers much like a post-asymptotic-giant-branch star and then become a white dwarf.

Stars that do not become red giants

Very-low-mass stars are fully convective and may continue to fuse hydrogen into helium for up to a trillion years until only a small fraction of the entire star is hydrogen. Luminosity and temperature steadily increase during this time, just as for more-massive main-sequence stars, but the length of time involved means that the temperature eventually increases by about 50% and the luminosity by around 10 times. Eventually the level of helium increases to the point where the star ceases to be fully convective and the remaining hydrogen locked in the core is consumed in only a few billion more years. Depending on mass, the temperature and luminosity continue to increase for a time during hydrogen shell burning, the star can become hotter than the Sun and tens of times more luminous than when it formed although still not as luminous as the Sun. After some billions more years, they start to become less luminous and cooler even though hydrogen shell burning continues. These become cool helium white dwarfs.

Very-high-mass stars develop into supergiants that follow an evolutionary track that takes them back and forth horizontally over the H–R diagram, at the right end constituting red supergiants. These usually end their life as a type II supernova. The most massive stars can become Wolf–Rayet stars without becoming giants or supergiants at all.

Planets

This section needs to be updated. The reason given is: May be outdated. Please help update this article to reflect recent events or newly available information. (April 2015)

Prospects for habitability

Although traditionally it has been suggested the evolution of a star into a red giant will render its planetary system, if present, uninhabitable, some research suggests that, during the evolution of a 1 M star along the red-giant branch, it could harbor a habitable zone for several billion years at 2 astronomical units (AU) out to around 100 million years at 9 AU out, giving perhaps enough time for life to develop on a suitable world. After the red-giant stage, there would for such a star be a habitable zone between 7 and 22 AU for an additional one billion years. Later studies have refined this scenario, showing how for a 1 M star the habitable zone lasts from 100 million years for a planet with an orbit similar to that of Mars to 210 million years for one that orbits at Saturn's distance to the Sun, the maximum time (370 million years) corresponding for planets orbiting at the distance of Jupiter. However, planets orbiting a 0.5 M star in equivalent orbits to those of Jupiter and Saturn would be in the habitable zone for 5.8 billion years and 2.1 billion years, respectively; for stars more massive than the Sun, the times are considerably shorter.

Enlargement of planets

As of 2023, several hundred giant planets have been discovered around giant stars. However, these giant planets are more massive than the giant planets found around solar-type stars. This could be because giant stars are more massive than the Sun (less massive stars will still be on the main sequence and will not have become giants yet) and more massive stars are expected to have more massive planets. However, the masses of the planets that have been found around giant stars do not correlate with the masses of the stars; therefore, the planets could be growing in mass during the stars' red giant phase. The growth in planet mass could be partly due to accretion from stellar wind, although a much larger effect would be Roche lobe overflow causing mass-transfer from the star to the planet when the giant expands out to the orbital distance of the planet. (A similar process in multiple star systems is believed to be the cause of most novas and type Ia supernovas.)

Examples

Many of the well-known bright stars are red giants, because they are luminous and moderately common. The red-giant branch variable star Gamma Crucis is the nearest M-class giant star at 88 light-years. The K1.5 red-giant branch star Arcturus is 36 light-years away.

Red-giant branch

Red-clump giants

Asymptotic giant branch

The Sun as a red giant

Main article: End of the Sun

The Sun will exit the main sequence in approximately 5 billion years and start to turn into a red giant. As a red giant, the Sun will grow so large (over 200 times its present-day radius: ~215 R; ~1 AU) that it will engulf Mercury, Venus, and likely Earth. It will lose 38% of its mass growing, then will die into a white dwarf.

References

  1. Boothroyd, A. I.; Sackmann, I. -J. (1999). "The CNO Isotopes: Deep Circulation in Red Giants and First and Second Dredge-up". The Astrophysical Journal. 510 (1): 232–250. arXiv:astro-ph/9512121. Bibcode:1999ApJ...510..232B. doi:10.1086/306546. S2CID 561413.
  2. Suzuki, Takeru K. (2007). "Structured Red Giant Winds with Magnetized Hot Bubbles and the Corona/Cool Wind Dividing Line". The Astrophysical Journal. 659 (2): 1592–1610. arXiv:astro-ph/0608195. Bibcode:2007ApJ...659.1592S. doi:10.1086/512600. S2CID 13957448.
  3. Habing, Harm J.; Olofsson, Hans (2003). "Asymptotic giant branch stars". Asymptotic Giant Branch Stars. Bibcode:2003agbs.conf.....H.
  4. Deutsch, A. J. (1970). "Chromospheric Activity in Red Giants, and Related Phenomena". Ultraviolet Stellar Spectra and Related Ground-Based Observations. Vol. 36. pp. 199–208. Bibcode:1970IAUS...36..199D. doi:10.1007/978-94-010-3293-3_33. ISBN 978-94-010-3295-7.
  5. Vlemmings, Wouter; Khouri, Theo; O’Gorman, Eamon; De Beck, Elvire; Humphreys, Elizabeth; Lankhaar, Boy; Maercker, Matthias; Olofsson, Hans; Ramstedt, Sofia; Tafoya, Daniel; Takigawa, Aki (December 2017). "The shock-heated atmosphere of an asymptotic giant branch star resolved by ALMA". Nature Astronomy. 1 (12): 848–853. arXiv:1711.01153. Bibcode:2017NatAs...1..848V. doi:10.1038/s41550-017-0288-9. ISSN 2397-3366. S2CID 119393687.
  6. O’Gorman, E.; Harper, G. M.; Ohnaka, K.; Feeney-Johansson, A.; Wilkeneit-Braun, K.; Brown, A.; Guinan, E. F.; Lim, J.; Richards, A. M. S.; Ryde, N.; Vlemmings, W. H. T. (June 2020). "ALMA and VLA reveal the lukewarm chromospheres of the nearby red supergiants Antares and Betelgeuse". Astronomy & Astrophysics. 638: A65. arXiv:2006.08023. Bibcode:2020A&A...638A..65O. doi:10.1051/0004-6361/202037756. ISSN 0004-6361. S2CID 219484950.
  7. Wedemeyer, Sven; Kučinskas, Arūnas; Klevas, Jonas; Ludwig, Hans-Günter (1 October 2017). "Three-dimensional hydrodynamical CO5BOLD model atmospheres of red giant stars - VI. First chromosphere model of a late-type giant". Astronomy & Astrophysics. 606: A26. arXiv:1705.09641. Bibcode:2017A&A...606A..26W. doi:10.1051/0004-6361/201730405. ISSN 0004-6361. S2CID 119510487.
  8. Schwarzschild, Martin (1975). "On the scale of photospheric convection in red giants and supergiants". Astrophysical Journal. 195: 137–144. Bibcode:1975ApJ...195..137S. doi:10.1086/153313.
  9. ^ Laughlin, G.; Bodenheimer, P.; Adams, F. C. (1997). "The End of the Main Sequence". The Astrophysical Journal. 482 (1): 420–432. Bibcode:1997ApJ...482..420L. doi:10.1086/304125.
  10. ^ Zeilik, Michael A.; Gregory, Stephan A. (1998). Introductory Astronomy & Astrophysics (4th ed.). Saunders College Publishing. pp. 321–322. ISBN 0-03-006228-4.
  11. "Stars". NASA Science Mission Directorate. 16 March 2012. Retrieved 29 August 2023.
  12. Tiago L. Campante; Nuno C. Santos; Mário J. P. F. G. Monteiro (3 November 2017). Asteroseismology and Exoplanets: Listening to the Stars and Searching for New Worlds: IVth Azores International Advanced School in Space Sciences. Springer. pp. 99–. ISBN 978-3-319-59315-9.
  13. ^ Fagotto, F.; Bressan, A.; Bertelli, G.; Chiosi, C. (1994). "Evolutionary sequences of stellar models with new radiative opacities. IV. Z=0.004 and Z=0.008". Astronomy and Astrophysics Supplement Series. 105: 29. Bibcode:1994A&AS..105...29F.
  14. Alves, David R.; Sarajedini, Ata (1999). "The Age-dependent Luminosities of the Red Giant Branch Bump, Asymptotic Giant Branch Bump, and Horizontal Branch Red Clump". The Astrophysical Journal. 511 (1): 225–234. arXiv:astro-ph/9808253. Bibcode:1999ApJ...511..225A. doi:10.1086/306655. S2CID 18834541.
  15. Sackmann, I. -J.; Boothroyd, A. I.; Kraemer, K. E. (1993). "Our Sun. III. Present and Future". The Astrophysical Journal. 418: 457. Bibcode:1993ApJ...418..457S. doi:10.1086/173407.
  16. Reiners, Ansgar; Basri, Gibor (2009). "On the magnetic topology of partially and fully convective stars". Astronomy and Astrophysics. 496 (3): 787. arXiv:0901.1659. Bibcode:2009A&A...496..787R. doi:10.1051/0004-6361:200811450. S2CID 15159121.
  17. Brainerd, Jerome James (16 February 2005). "Main-Sequence Stars". Stars. The Astrophysics Spectator. Archived from the original on 6 December 2006. Retrieved 29 December 2006.
  18. Richmond, Michael. "Late stages of evolution for low-mass stars". Retrieved 29 December 2006.
  19. Crowther, P. A. (2007). "Physical Properties of Wolf-Rayet Stars". Annual Review of Astronomy and Astrophysics. 45 (1): 177–219. arXiv:astro-ph/0610356. Bibcode:2007ARA&A..45..177C. doi:10.1146/annurev.astro.45.051806.110615. S2CID 1076292.
  20. Georges Meynet; Cyril Georgy; Raphael Hirschi; Andre Maeder; et al. (12–16 July 2010). G. Rauw; M. De Becker; Y. Nazé; J.-M. Vreux; et al. (eds.). "Red Supergiants, Luminous Blue Variables and Wolf-Rayet stars: The single massive star perspective". Société Royale des Sciences de Liège, Bulletin (Proceedings of the 39th Liège Astrophysical Colloquium). v1. 80 (39). Liège: 266–278. arXiv:1101.5873. Bibcode:2011BSRSL..80..266M.
  21. Lopez, Bruno; Schneider, Jean; Danchi, William C. (2005). "Can Life Develop in the Expanded Habitable Zones around Red Giant Stars?". The Astrophysical Journal. 627 (2): 974–985. arXiv:astro-ph/0503520. Bibcode:2005ApJ...627..974L. doi:10.1086/430416. S2CID 17075384.
  22. Ramirez, Ramses M.; Kaltenegger, Lisa (2016). "Habitable Zones of Post-Main Sequence Stars". The Astrophysical Journal. 823 (1): 6. arXiv:1605.04924. Bibcode:2016ApJ...823....6R. doi:10.3847/0004-637X/823/1/6. S2CID 119225201.
  23. "Planetary Systems". exoplanetarchive.ipac.caltech.edu. Retrieved 10 August 2023.
  24. Jones, M. I.; Jenkins, J. S.; Bluhm, P.; Rojo, P.; Melo, C. H. F. (2014). "The properties of planets around giant stars". Astronomy & Astrophysics. 566: A113. arXiv:1406.0884. Bibcode:2014A&A...566A.113J. doi:10.1051/0004-6361/201323345. S2CID 118396750.
  25. Ireland, M. J.; et al. (May 2004). "Multiwavelength diameters of nearby Miras and semiregular variables". Monthly Notices of the Royal Astronomical Society. 350 (1): 365–374. arXiv:astro-ph/0402326. Bibcode:2004MNRAS.350..365I. doi:10.1111/j.1365-2966.2004.07651.x. S2CID 15830460.
  26. Abia, C.; Palmerini, S.; Busso, M.; Cristallo, S. (2012). "Carbon and oxygen isotopic ratios in Arcturus and Aldebaran. Constraining the parameters for non-convective mixing on the red giant branch". Astronomy & Astrophysics. 548: A55. arXiv:1210.1160. Bibcode:2012A&A...548A..55A. doi:10.1051/0004-6361/201220148. S2CID 56386673.
  27. ^ Howes, Louise M.; Lindegren, Lennart; Feltzing, Sofia; Church, Ross P.; Bensby, Thomas (February 2019). "Estimating stellar ages and metallicities from parallaxes and broadband photometry: successes and shortcomings". Astronomy & Astrophysics. 622: A27. arXiv:1804.08321. Bibcode:2019A&A...622A..27H. doi:10.1051/0004-6361/201833280. ISSN 0004-6361.
  28. Alves, David R. (2000). "K-Band Calibration of the Red Clump Luminosity". The Astrophysical Journal. 539 (2): 732–741. arXiv:astro-ph/0003329. Bibcode:2000ApJ...539..732A. doi:10.1086/309278. S2CID 16673121.
  29. Nola Taylor Redd. "Red Giant Stars: Facts, Definition & the Future of the Sun". space.com. Retrieved 20 February 2016.
  30. Schröder, K.-P.; Connon Smith, R. (2008). "Distant future of the Sun and Earth revisited". Monthly Notices of the Royal Astronomical Society. 386 (1): 155–163. arXiv:0801.4031. Bibcode:2008MNRAS.386..155S. doi:10.1111/j.1365-2966.2008.13022.x. S2CID 10073988.
  31. Siegel, Ethan (8 February 2020). "Ask Ethan: Will The Earth Eventually Be Swallowed By The Sun?". Forbes. Retrieved 12 March 2021.

External links

Media related to Red giants at Wikimedia Commons

Stars
Formation
Evolution
Classification
Remnants
Hypothetical
Nucleosynthesis
Structure
Properties
Star systems
Earth-centric
observations
Lists
Related
Portals:

Categories: