User:아나코공산주의자/sandbox

Not to be confused with List of most massive stars.

Relative sizes of the planets in the Solar System and several well-known stars:

1. Mercury < Mars < Venus < Earth
2. Earth < Neptune < Uranus < Saturn < Jupiter
3. Jupiter < Wolf 359 < Sun < Sirius A
4. Sirius A < Pollux < Arcturus < Aldebaran
5. Aldebaran < Rigel A < Antares A < Betelgeuse
6. Betelgeuse < Mu Cephei < VV Cephei A < VY Canis Majoris

Below are lists of the largest stars currently known, ordered by radius and separated into categories by galaxy. The unit of measurement used is the radius of the Sun (approximately 695,700 km; 432,300 mi).^[1]

The angular diameters of stars can be measured directly using stellar interferometry. Other methods can use lunar occultations or from eclipsing binaries, which can be used to test indirect methods of finding stellar radii. Only a few useful supergiant stars can be occulted by the Moon, including Antares A (Alpha Scorpii A). Examples of eclipsing binaries are Epsilon Aurigae (Almaaz), VV Cephei, and V766 Centauri (HR 5171). Angular diameter measurements can be inconsistent because the boundary of the very tenuous atmosphere (opacity) differs depending on the wavelength of light in which the star is observed.

Uncertainties remain with the membership and order of the lists, especially when deriving various parameters used in calculations, such as stellar luminosity and effective temperature. Often stellar radii can only be expressed as an average or be within a large range of values. Values for stellar radii vary significantly in different sources and for different observation methods.

All the sizes stated in these lists have inaccuracies and may be disputed. The lists are still a work in progress and parameters are prone to change.

Caveats

Various issues exist in determining accurate radii of the largest stars, which in many cases do display significant errors. The following lists are generally based on various considerations or assumptions; these include:

• Stellar radii or diameters are usually derived only approximately using Stefan–Boltzmann law for the deduced stellar luminosity and effective surface temperature.
• Stellar distances, and their errors, for most stars, remain uncertain or poorly determined.
• Many supergiant stars have extended atmospheres, and many are within opaque dust shells, making their true effective temperatures and surfaces highly uncertain.^{[citation needed]}
• Many extended supergiant atmospheres also significantly change in size over time, regularly or irregularly pulsating over several months or years as variable stars. This makes adopted luminosities poorly known and may significantly change the quoted radii.
• Other direct methods for determining stellar radii rely on lunar occultations or from eclipses in binary systems. This is only possible for a very small number of stars.
• Most distance estimates for red supergiants come from stellar cluster or association membership, because it is difficult to calculate accurate distances for red supergiants that are not part of any cluster or association.
• In these lists are some examples of extremely distant extragalactic stars, which may have slightly different properties and natures than the currently largest known stars in the Milky Way. For example, some red supergiants in the Magellanic Clouds are suspected to have slightly different limiting temperatures and luminosities. Such stars may exceed accepted limits by undergoing large eruptions or changing their spectral types over just a few months (or potentially years).^[2][3]

Lists

The following lists show the largest known stars based on the host galaxy.

Milky Way

List of the largest known stars in the Milky Way^[a]

Star name	Solar radii (Sun = 1)	Method[b]	Notes
Stephenson 2-18	2,150[4]	L/Teff
Orbit of Saturn	2,047 – 2,050[5][c]		Reported for reference
NML Cygni	1,639[6]	L/Teff
The above radii are larger than what stellar evolution theory predicts, and are thus potentially unreliable
Theoretical limit of star size (Milky Way)	~1,500[7]		This value comes from the rough average radii of the three largest stars studied in the paper. It is consistent with the largest possible stellar radii predicted from the current evolutionary theory, and it is believed that stars above this radius would be too unstable and simply do not form.[7] Reported for reference
HV 888 (WOH S140)	1,477	L/Teff
AH Scorpii	1,411±124[8]	AD
GCIRS 7	1,170±60[9]	AD
EV Carinae	1,168	?
HD 143183	1,147	L/Teff
HV 11423	1,060	L/Teff
BC Cygni	1,031[10]	L/Teff	A more detailed but older study gives values of 1,081 (856 - 1,375) for the year 2000, and 1,303 (1,021 - 1,553) for the year 1900.[11]
6 Geminorum (BU Geminorum)	821+60 −27[7]	L/Teff
BI Cygni	797[10]	L/Teff
Betelgeuse (α Orionis)	764+116 −62[12]	?	Tenth brightest star in the night sky.[13]
CK Carinae	761[7]	L/Teff
V354 Cephei	1,520±304[7]	L/Teff
KY Cygni	1,420±284–(2,850±570)[7]	L/Teff
Westerlund 1 W237 (Westerlund 1 BKS B)	1,241±70[14]	L/Teff
IRC -10414	~1,200[15]	L/Teff
PZ Cassiopeiae	1,190±238(–1,940±388)[7]	L/Teff
Westerlund 1 W26 (Westerlund 1 BKS AS)	1,165±58–1,221±120[14]	L/Teff
Orbit of Jupiter	1,114.5–1,115.8[5][c]		Reported for reference
V766 Centauri Aa	1,110±50[16]	?	V766 Centauri Aa is a rare variable yellow supergiant.
RT Carinae	1,090±218[7]	L/Teff
V396 Centauri	1,070±214[7] – 1,145.31[17]	L/Teff & ?
V602 Carinae	1,050±165[18]	AD
KW Sagittarii	1,009±142[8]	AD
AZ Cygni	911+57 −50[19]	AD
NSV 25875	891[20]	L/Teff
V437 Scuti	874[20]	L/Teff
LL Pegasi	869[20]	L/Teff
V669 Cassiopeiae	859[20]	L/Teff
Westerlund 1 W20 (Westerlund 1 BKS D)	858±48[14]	L/Teff
VX Sagittarii	853[20]-1,335±215[21]	L/Teff
μ Cephei (Herschel's Garnet Star)	830[20]-972±228[22]	AD
V1185 Scorpii	830[20]	L/Teff
CW Leonis	826[20]	L/Teff
LP Andromedae	815[20]	L/Teff
RT Ophiuchi	801±217[23]	AD
V354 Cephei	1,520±304[7]	? & L/Teff
BO Carinae	790±158[7]	L/Teff
S Persei	780±156(–1,230±246)[7]	L/Teff
SU Persei	780±156[7] – 971.405[17]	L/Teff
RS Persei	770±30[24]	AD
V355 Cephei	770±154[7]	L/Teff
GU Cephei A	766.486[17]	?
HD 303250	750±150[7]	L/Teff
UU Pegasi	742±193[23]	AD
Westerlund 1 W75 (Westerlund 1 BKS E)	722±36[14]	L/Teff
V Camelopardalis	716±185[23]	AD
V923 Centauri	715.539[17]	?
V528 Carinae	700±140[7]	L/Teff
The following well-known stars are listed for the purpose of comparison.
Antares A (α Scorpii)	680[25]	AD	Fourteenth brightest star in the night sky.[13]
RW Cygni	676.08[10] – 980±196[7] – 1,502.16[17]	?
TZ Cassiopeiae	645.65,[10] 766.813[17] – 800±160[7]	L/Teff
R Hydrae	631[20]	L/Teff
NO Aurigae	630±126[7] – 1,481.85[17]	L/Teff
DU Crucis	629.63[17]	?
IX Carinae	620.718[17]920±184[7]	L/Teff
VY Canis Majoris	605[26] – 1,420±120,[27][28][29] 2,069[30][31]	L/Teff & AD
TV Geminorum	~620–710[32]	L/Teff
R Sculptoris	617[20]	L/Teff
V Hydrae	609[20]	L/Teff
V419 Cephei	590±118[7]	L/Teff
119 Tauri (CE Tauri)	587±85–593±86[33]	AD
R Leonis Minoris	569±146[23]	AD
TX Camelopardalis	560[20]	L/Teff
S Orionis	545±142[23]	AD
Mira A (ο Ceti)	541[20]	L/Teff
VV Cephei A	515.632[17] – 1,050[34]	? & AD
T Persei	510±20[24] – 622.081[17]	AD
V1427 Aquilae	507[20]	L/Teff
HR Carinae B	500±150[35]	AD
QY Puppis	485.319[17]	?
V838 Monocerotis	464[36]–730[37]	? & AD
S Pegasi	459±135[23]	AD
S Coronae Borealis	457±116[23]	AD
IK Tauri (NML Tauri)	451[20]	L/Teff
π1 Gruis	447[20]	L/Teff
R Aquarii	438±114[23]	AD
U Herculis	431±114[23]	AD
NR Vulpeculae	426.58,[10] 668.395[17]–980±196[7]	L/Teff
Unurgunite (σ Canis Majoris)	420±84[7]	L/Teff
V810 Centauri	420[38]	L/Teff
W Aquilae	419[20]	L/Teff
R Cassiopeiae	410[20] - 593±181[23]	L/Teff & AD
R Aurigae	407±105[23]	AD
R Leporis	400±90[39]	?
U Hydrae	395[20]	L/Teff
S Scuti	386[20]	L/Teff
MZ Puppis	376.973[17]	?
Westerlund 1 W243 (Westerlund 1 BKS G)	376.9[40]	?
U Orionis	370±96[23]	AD
R Aquilae	354±99[23]	AD
V4650 Sagittarii	350[41]	?
R Serpentis	328±86[23]	AD
U Antliae	325[20]	L/Teff
Orbit of Mars	322–323.1[5][c]		Reported for reference
5 Lacertae (V412 Lacertae)	319.2+26.6 −32.0[42]	AD
T Ceti	312[20]	L/Teff
Y Canum Venaticorum (La Superba)	307[20]	L/Teff
Pistol Star (V4647 Sagittarii)	306[41]	?
R Leonis	299[20] - 409±105[23]	AD & L/Teff
R Doradus (P Doradus)	298±21[43]	AD
S Ursae Minoris	296±82[23]	AD
Rasalgethi A (α Herculis)	284±60 (264–303)[44]	L/Teff
ο1 Canis Majoris	280±56[7]	L/Teff
R Canum Venaticorum	279±75[23]	AD
R Aquilae	259±67[23]	AD
S Doradus	240±140[45]	?
V424 Lacertae	239±80[46]–260±52[7]	AD & L/Teff
SW Cephei	234.42[10]	L/Teff
W Hydrae	229[20]	L/Teff
NGC 6910 RLP 10 (Cygnus OB2-12)	229[47]	L/Teff
HR Carinae A	220±60[35]	AD
Wezen (δ Canis Majoris)	215±66[48]	AD	Thirty-sixth brightest star in the night sky.[13]
Orbit of Earth (~1 AU)	214[5][c]		Reported for reference
Enif (ε Pegasi)	210.37 – 210.69[49]	?
Suhail (λ Velorum)	210[50]	?
Deneb (α Cygni)	203±17[51]	?	Eighteenth brightest star in the night sky.[13]
Orbit of Venus	158.6[5][c]		Reported for reference
Orbit of Mercury	82.9–84.6[5][c]		Reported for reference
Vega (α Lyrae)	2.726±0.006 × 2.418±0.012[52]		Fifth brightest star in the night sky.[13] Reported for reference
Sun	1		The largest object in the Solar System. Reported for reference

Magellanic Clouds

List of the largest known stars in the Magellanic Clouds

Star name	Solar radii (Sun = 1)	Galaxy	Method[d]	Notes
WOH G64	1,540[53]	Large Magellanic Cloud	L/Teff	Surrounded by a large dust cloud.

Other galaxies (within the Local Group)

List of the largest known stars in other galaxies (within the Local Group)

Star name	Solar radii (Sun = 1)	Galaxy	Method[e]	Notes
Sextans A 10	995±130[54]	Sextans A	L/Teff
Sextans A 5	870±145[54]	Sextans A	L/Teff
Sextans A 7	710±100[54]	Sextans A	L/Teff
IC 10 3	685±90[54]	IC 10	L/Teff
WLM 14	610±80[54]	WLM	L/Teff
Sextans B 1	565±70[54]	Sextans B	L/Teff
IC 1613 2	560±70[54]	IC 1613	L/Teff
WLM 12	430±70[54]	WLM	L/Teff
IC 10 5	420±50[54]	IC 10	L/Teff
Sextans B 2	405±90[54]	Sextans B	L/Teff
WLM 13	380±50[54]	WLM	L/Teff
Sextans A 6	350±40[54]	Sextans A	L/Teff
Pegasus 1	340±50[54]	Pegasus Dwarf	L/Teff
Sextans A 4	335±40[54]	Sextans A	L/Teff
WLM 11	310±50[54]	WLM	L/Teff
IC 1613 1	300±40[54]	IC 1613	L/Teff
IC 10 2	280±30[54]	IC 10	L/Teff
Pegasus 2	260±40[54]	Pegasus Dwarf	L/Teff
Sextans A 8	260±60[54]	Sextans A	L/Teff
Sextans A 9	230±50[54]	Sextans A	L/Teff
IC 10 4	200±25[54]	IC 10	L/Teff
IC 10 1	165±60[54]	IC 10	L/Teff
IC 10 6	160±25[54]	IC 10	L/Teff
Phoenix 3	90±15[54]	Phoenix Dwarf	L/Teff

Outside the Local Group

List of the largest known stars in galaxies outside the Local Group

Star name	Solar radii (Sun = 1)	Galaxy	Group	Method[f]	Notes
NGC 2363-V1	194–356[55]	NGC 2363	M81 Group	?

Notes

1. Currently only contains radii that are stated in the cited papers
2. Methods for calculating the radius:
   • AD: radius calculated from angular diameter and distance
   • L/T_eff: radius calculated from bolometric luminosity and effective temperature
3. At the J2000 epoch
4. Methods for calculating the radius:
   • L/T_eff: radius calculated from bolometric luminosity and effective temperature
5. Methods for calculating the radius:
   • L/T_eff: radius calculated from bolometric luminosity and effective temperature
6. Methods for calculating the radius:
   • L/T_eff: radius calculated from bolometric luminosity and effective temperature

References

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See also

• Constellation
• Lists of stars
• List of most massive stars
• List of most luminous stars
• List of hottest stars
• List of coolest stars
• List of most massive black holes
• List of largest nebulae
• List of largest galaxies
• List of largest cosmic structures
• List of largest exoplanets
• List of star extremes
• Star

External links

• Giant Stars An interactive website comparing the Earth and the Sun to some of the largest known stars
• Three largest stars identified BBC News
• What is the Biggest Star in the Universe? Universe Today

Category:Hypergiants Category:Supergiants Largest Stars, largest Largest stars