fbpx
Wikipedia

Small Magellanic Cloud

January 01, 1970

The Small Magellanic Cloud (SMC) is a dwarf galaxy near the Milky Way.[5] Classified as a dwarf irregular galaxy, the SMC has a D25 isophotal diameter of about 5.78 kiloparsecs (18,900 light-years),[1][3] and contains several hundred million stars.[5] It has a total mass of approximately 7 billion solar masses.[6] At a distance of about 200,000 light-years, the SMC is among the nearest intergalactic neighbors of the Milky Way and is one of the most distant objects visible to the naked eye.

SMC
The Small Magellanic Cloud
(Source: Digitized Sky Survey 2)
Observation data (J2000 epoch)
ConstellationTucana and Hydrus
Right ascension00h 52m 44.8s[1]
Declination−72° 49′ 43″[1]
Redshift0.000527[1]
Distance203.7 ± 1.5 kly (62.44 ± 0.47 kpc)[2]
Apparent magnitude (V)2.7[1]
Characteristics
TypeSB(s)m pec[1]
Number of stars3 billion[4]
Size5.78 kiloparsecs (18,900 light-years)[1]
(diameter; 25.0 mag/arcsec2 B-band isophote)[3]
Apparent size (V)5° 20′ × 3° 5′[1]
Notable featuresCompanion dwarf to the
Milky Way
Other designations
SMC,[1] NGC 292,[1] PGC 3085,[1] Nubecula Minor[1]

The SMC is visible from the entire Southern Hemisphere and can be fully glimpsed low above the southern horizon from latitudes south of about 15° north. The galaxy is located across the constellation of Tucana and part of Hydrus, appearing as a faint hazy patch resembling a detached piece of the Milky Way. The SMC has an average apparent diameter of about 4.2° (8 times the Moon's) and thus covers an area of about 14 square degrees (70 times the Moon's). Since its surface brightness is very low, this deep-sky object is best seen on clear moonless nights and away from city lights. The SMC forms a pair with the Large Magellanic Cloud (LMC), which lies 20° to the east, and, like the LMC, is a member of the Local Group. It is currently a satellite of the Milky Way, but is likely a former satellite of the LMC.

Observation history edit

 
Panoramic Large and Small Magellanic Clouds as seen from ESO's VLT observation site. The galaxies are on the left side of the image.
 
Constellation of Tucana: the SMC is the green shape at the south (bottom) of picture

In the southern hemisphere, the Magellanic clouds have long been included in the lore of native inhabitants, including south sea islanders and indigenous Australians. Persian astronomer Al Sufi mentions them in his Book of Fixed Stars, repeating a quote by the polymath Ibn Qutaybah, but had not observed them himself. European sailors may have first noticed the clouds during the Middle Ages when they were used for navigation. Portuguese and Dutch sailors called them the Cape Clouds, a name that was retained for several centuries. During the circumnavigation of the Earth by Ferdinand Magellan in 1519–1522, they were described by Antonio Pigafetta as dim clusters of stars.[7] In Johann Bayer's celestial atlas Uranometria, published in 1603, he named the smaller cloud, Nubecula Minor.[8] In Latin, Nubecula means a little cloud.[9]

 
Small Magellanic Cloud as photographed by an amateur astronomer. Unrelated stars have been edited out.

Between 1834 and 1838, John Frederick William Herschel made observations of the southern skies with his 14-inch (36 cm) reflector from the Royal Observatory. While observing the Nubecula Minor, he described it as a cloudy mass of light with an oval shape and a bright center. Within the area of this cloud he catalogued a concentration of 37 nebulae and clusters.[10]

In 1891, Harvard College Observatory opened an observing station at Arequipa in Peru. Between 1893 and 1906, under the direction of Solon Bailey, the 24-inch (610 mm) telescope at this site was used to survey photographically both the Large and Small Magellanic Clouds.[11] Henrietta Swan Leavitt, an astronomer at the Harvard College Observatory, used the plates from Arequipa to study the variations in relative luminosity of stars in the SMC. In 1908, the results of her study were published, which showed that a type of variable star called a "cluster variable", later called a Cepheid variable after the prototype star Delta Cephei, showed a definite relationship between the variability period and the star's apparent brightness. Leavitt realized that since all the stars in the SMC are roughly the same distance from Earth, this result implied that there is similar relationship between period and absolute brightness.[12] This important period-luminosity relation allowed the distance to any other cepheid variable to be estimated in terms of the distance to the SMC.[13] She hoped a few Cepheid variables could be found close enough to Earth so that their parallax, and hence distance from Earth, could be measured. This soon happened, allowing Cepheid variables to be used as standard candles, facilitating many astronomical discoveries.[14]

Using this period-luminosity relation, in 1913 the distance to the SMC was first estimated by Ejnar Hertzsprung. First he measured thirteen nearby cepheid variables to find the absolute magnitude of a variable with a period of one day. By comparing this to the periodicity of the variables as measured by Leavitt, he was able to estimate a distance of 10,000 parsecs (30,000 light years) between the Sun and the SMC.[15] This later proved to be a gross underestimate of the true distance, but it did demonstrate the potential usefulness of this technique.[16]

Announced in 2006, measurements with the Hubble Space Telescope suggest the Large and Small Magellanic Clouds may be moving too fast to be orbiting the Milky Way.[17]

Features edit

 
VISTA's view of the Small Magellanic Cloud. 47 Tucanae (NGC 104) is visible to the right of the Small Magellanic Cloud.

The SMC contains a central bar structure, and astronomers speculate that it was once a barred spiral galaxy that was disrupted by the Milky Way to become somewhat irregular.[18]

There is a bridge of gas connecting the Small Magellanic Cloud with the Large Magellanic Cloud (LMC), which is evidence of tidal interaction between the galaxies.[19] This bridge of gas is a star-forming site.[20] The Magellanic Clouds have a common envelope of neutral hydrogen, indicating they have been gravitationally bound for a long time.

In 2017, using the Dark Energy Survey plus MagLiteS data, a stellar over-density associated with the Small Magellanic Cloud was discovered, which is probably the result of interactions between the SMC and LMC.[21]

 
The Small Magellanic Cloud pictured by the Hubble Space Telescope[22]

X-ray sources edit

The Small Magellanic Cloud contains a large and active population of X-ray binaries. Recent star formation has led to a large population of massive stars and high-mass X-ray binaries (HMXBs) which are the relics of the short-lived upper end of the initial mass function. The young stellar population and the majority of the known X-ray binaries are concentrated in the SMC's Bar. HMXB pulsars are rotating neutron stars in binary systems with Be-type (spectral type 09-B2, luminosity classes V–III) or supergiant stellar companions. Most HMXBs are of the Be type which account for 70% in the Milky Way and 98% in the SMC.[23] The Be-star equatorial disk provides a reservoir of matter that can be accreted onto the neutron star during periastron passage (most known systems have large orbital eccentricity) or during large-scale disk ejection episodes. This scenario leads to strings of X-ray outbursts with typical X-ray luminosities Lx = 1036–1037 erg/s, spaced at the orbital period, plus infrequent giant outbursts of greater duration and luminosity.[24]

Monitoring surveys of the SMC performed with NASA's Rossi X-ray Timing Explorer (RXTE)[25] see X-ray pulsars in outburst at more than 1036 erg/s and have counted 50 by the end of 2008. The ROSAT and ASCA missions detected many faint X-ray point sources,[26] but the typical positional uncertainties frequently made positive identification difficult. Recent studies using XMM-Newton[27] and Chandra[28] have now cataloged several hundred X-ray sources in the direction of the SMC, of which perhaps half are considered likely HMXBs, and the remainder a mix of foreground stars, and background AGN.

No X-rays above background were observed from the Magellanic Clouds during the September 20, 1966, Nike-Tomahawk flight.[29] Balloon observation from Mildura, Australia, on October 24, 1967, of the SMC set an upper limit of X-ray detection.[30] An X-ray astronomy instrument was carried aboard a Thor missile launched from Johnston Atoll on September 24, 1970, at 12:54 UTC for altitudes above 300 km, to search for the Small Magellanic Cloud.[31] The SMC was detected with an X-ray luminosity of 5×1038 erg/s in the range 1.5–12 keV, and 2.5×1039 erg/s in the range 5–50 keV for an apparently extended source.[31]

The fourth Uhuru catalog lists an early X-ray source within the constellation Tucana: 4U 0115-73 (3U 0115-73, 2A 0116-737, SMC X-1).[32] Uhuru observed the SMC on January 1, 12, 13, 16, and 17, 1971, and detected one source located at 01149-7342, which was then designated SMC X-1.[33] Some X-ray counts were also received on January 14, 15, 18, and 19, 1971.[34] The third Ariel 5 catalog (3A) also contains this early X-ray source within Tucana: 3A 0116-736 (2A 0116-737, SMC X-1).[35] The SMC X-1, a HMXRB, is at J2000 right ascension (RA) 01h 15m 14s declination (Dec) 73° 42′ 22″.

Two additional sources detected and listed in 3A include SMC X-2 at 3A 0042-738 and SMC X-3 at 3A 0049-726.[35]

Mini Magellanic Cloud (MMC) edit

It has been proposed by astrophysicists D. S. Mathewson, V. L. Ford and N. Visvanathan that the SMC may in fact be split in two, with a smaller section of this galaxy behind the main part of the SMC (as seen from Earth perspective), and separated by about 30,000 ly. They suggest the reason for this is due to a past interaction with the LMC that split the SMC, and that the two sections are still moving apart. They dubbed this smaller remnant the Mini Magellanic Cloud.[36][37]

In 2023, it was reported that the SMC is indeed two separate structures with distinct stellar and gaseous chemical compositions, separated by around 5 kiloparsecs.[38]

See also edit

References edit

  1. ^ a b c d e f g h i j k l "NASA/IPAC Extragalactic Database". Results for Small Magellanic Cloud. Retrieved 2006-12-01.
  2. ^ Graczyk, Dariusz; Pietrzyński, Grzegorz; Thompson, Ian B.; Gieren, Wolfgang; Zgirski, Bartłomiej; Villanova, Sandro; Górski, Marek; Wielgórski, Piotr; Karczmarek, Paulina; Narloch, Weronika; Pilecki, Bogumił; Taormina, Monica; Smolec, Radosław; Suchomska, Ksenia; Gallenne, Alexandre; Nardetto, Nicolas; Storm, Jesper; Kudritzki, Rolf-Peter; Kałuszyński, Mikołaj; Pych, Wojciech (2020). "A Distance Determination to the Small Magellanic Cloud with an Accuracy of Better than Two Percent Based on Late-type Eclipsing Binary Stars". The Astrophysical Journal. 904 (1): 13. arXiv:2010.08754. Bibcode:2020ApJ...904...13G. doi:10.3847/1538-4357/abbb2b. S2CID 224706414.
  3. ^ a b De Vaucouleurs, Gerard; De Vaucouleurs, Antoinette; Corwin, Herold G.; Buta, Ronald J.; Paturel, Georges; Fouque, Pascal (1991). Third Reference Catalogue of Bright Galaxies. Bibcode:1991rc3..book.....D.
  4. ^ Jonathan Powell (17 September 2018). Rare Astronomical Sights and Sounds. Springer. ISBN 978-3-319-97701-0.
  5. ^ a b Nemiroff, R.; Bonnell, J., eds. (2006-06-17). "The Small Cloud of Magellan". Astronomy Picture of the Day. NASA. Retrieved 2008-07-07.
  6. ^ Bekki, Kenji; Stanimirović, Snežana (2009-05-01). "The total mass and dark halo properties of the Small Magellanic Cloud". Monthly Notices of the Royal Astronomical Society. 395 (1). Oxford University Press (OUP): 342–350. arXiv:0807.2102. Bibcode:2009MNRAS.395..342B. doi:10.1111/j.1365-2966.2009.14514.x. ISSN 0035-8711. S2CID 18268139.
  7. ^ Westerlund, Bengt E. (1997). The Magellanic Clouds. Cambridge University Press. ISBN 978-0-521-48070-3.
  8. ^ O'Meara, Stephen James (2002). The Caldwell Objects. Cambridge University Press. ISBN 978-0-521-82796-6.
  9. ^ Lewis, Charlton Thomas; Kingery, Hugh Macmaster (1918). An elementary Latin dictionary. American Book Company. ISBN 978-0-19-910205-1.
  10. ^ Herschel, John Frederick William (1849). Outlines of Astronomy. Philadelphia: Lea & Blanchard. ISBN 978-0-665-18744-5.
  11. ^ Longair, Malcolm S. (2006). The Cosmic Century: A History of Astrophysics and Cosmology. Cambridge University Press. ISBN 978-0-521-47436-8.
  12. ^ Leavitt, Henrietta S. (1908). "1777 variables in the Magellanic Clouds". Annals of Harvard College Observatory. 60: 87–108. Bibcode:1908AnHar..60...87L.
  13. ^ Aparicio, Antonio; Herrero, Artemio; Sánchez, Francisco (1998). Stellar Astrophysics for the Local Group. Cambridge University Press. ISBN 978-0-521-56327-7.
  14. ^ Fernie, J.D. (December 1969). "The Period–Luminosity Relation: A Historical Review". Publications of the Astronomical Society of the Pacific. 81 (483): 707. Bibcode:1969PASP...81..707F. doi:10.1086/128847.
  15. ^ Gribbin, John R. (1999). The Birth of Time: How Astronomers Measured the Age of the Universe. Yale University Press. ISBN 978-0-300-08346-0.
  16. ^ Hoffleit, Dorrit (1992). "The Selector of Highlights: A Brief Biographical Sketch of Harlow Shapley". The Journal of the American Association of Variable Star Observers. 21 (2): 151–156. Bibcode:1992JAVSO..21..151H.
  17. ^ "Press release: Magellanic Clouds May Be Just Passing Through". Harvard University. January 9, 2007.
  18. ^ . NASA/IPAC. Archived from the original on 2015-11-07. Retrieved 2008-07-07.
  19. ^ Mathewson DS; Ford VL (1984). "Structure and Evolution of the Magellanic Clouds". IAU Symposium. 108: 125.
  20. ^ Heydari-Malayeri M; Meynadier F; Charmandaris V; Deharveng L; et al. (2003). "The stellar environment of SMC N81". Astron. Astrophys. 411 (3): 427–436. arXiv:astro-ph/0309126. Bibcode:2003A&A...411..427H. doi:10.1051/0004-6361:20031360. S2CID 8240730.
  21. ^ Adriano Pieres; et al. (2017). "A stellar over-density associated with the Small Magellanic Cloud". Monthly Notices of the Royal Astronomical Society. 468 (2): 1349–1360. arXiv:1612.03938. Bibcode:2017MNRAS.468.1349P. doi:10.1093/mnras/stx507.
  22. ^ "Head in the Clouds". Retrieved 2023-08-24.
  23. ^ Coe et al. 2005
  24. ^ Negueruela 1998 for a review
  25. ^ Laycock et al. 2005; Galache et al. 2008
  26. ^ Haberl & Sasaki 2000
  27. ^ Haberl et al. 2008; Haberl & Pietsch 2004
  28. ^ Antoniou et al. 2009; Edge et al. 2004, and Laycock et al. 2010
  29. ^ Chodil G; Mark H; Rodrigues R; Seward FD; et al. (Oct 1967). "X-Ray Intensities and Spectra from Several Cosmic Sources". Astrophys. J. 150 (10): 57–65. Bibcode:1967ApJ...150...57C. doi:10.1086/149312.
  30. ^ Lewin WHG; Clark GW; Smith WB (1968). "Search for X-rays from the Large and Small Magellanic Clouds". Nature. 220 (5164): 249–250. Bibcode:1968Natur.220..249L. doi:10.1038/220249b0. S2CID 4187949.
  31. ^ a b Price RE; Groves DJ; Rodrigues RM; Seward FD; et al. (Aug 1971). "X-Rays from the Magellanic Clouds". Astrophys. J. 168 (8): L7–9. Bibcode:1971ApJ...168L...7P. doi:10.1086/180773.
  32. ^ Forman W; Jones C; Cominsky L; Julien P; et al. (1978). "The fourth Uhuru catalog of X-ray sources". Astrophys. J. Suppl. Ser. 38: 357. Bibcode:1978ApJS...38..357F. doi:10.1086/190561.
  33. ^ Leong C; Kellogg E; Gursky H; Tananbaum H; et al. (Dec 1971). "X-Ray Emission from the Magellanic Clouds Observed by UHURU". Astrophys. J. 170 (12): L67–71. Bibcode:1971ApJ...170L..67L. doi:10.1086/180842.
  34. ^ Tananbaum HD (1973). "UHURU Results on Galactic X-ray Sources". In Bradt H; Giacconi R (eds.). X- and Gamma-Ray Astronomy. Vol. 55. Dordrecht, Holland: International Astronomical Union. pp. 9–28. Bibcode:1973IAUS...55....9T. doi:10.1007/978-94-010-2585-0_2. ISBN 978-90-277-0337-8.
  35. ^ a b McHardy IM; Lawrence A; Pye JP; Pounds KA (Dec 1981). "The Ariel V /3 A/ catalogue of X-ray sources. II - Sources at high galactic latitude /absolute value of B greater than 10 deg/". Monthly Notices of the Royal Astronomical Society. 197 (4): 893–919. Bibcode:1981MNRAS.197..893M. doi:10.1093/mnras/197.4.893.
  36. ^ Mathewson, D. S.; Ford, V. L.; Visvanathan, N. (1986). "The structure of the Small Magellanic Cloud". The Astrophysical Journal. 301: 664. Bibcode:1986ApJ...301..664M. doi:10.1086/163932. ISSN 0004-637X.
  37. ^ Crowl, Hugh H.; et al. (2001). "The Line-of-Sight Depth of Populous Clusters in the Small Magellanic Cloud". The Astronomical Journal. 122 (1): 220–231. arXiv:astro-ph/0104227v1. Bibcode:2001AJ....122..220C. doi:10.1086/321128. ISSN 0004-6256. S2CID 45263795.
  38. ^ Murray, Claire E.; Hasselquist, Sten; Peek, Joshua E. G.; Christina Willecke Lindberg; Almeida, Andres; Choi, Yumi; Craig, Jessica E. M.; Denes, Helga; Dickey, John M.; Di Teodoro, Enrico M.; Federrath, Christoph; Gerrard, Isabella A.; Gibson, Steven J.; Leahy, Denis; Lee, Min-Young; Lynn, Callum; Yik Ki Ma; Marchal, Antoine; McClure-Griffiths, N. M.; Nidever, David; Nguyen, Hiep; Pingel, Nickolas M.; Tarantino, Elizabeth; Uscanga, Lucero; van Loon, Jacco Th. (2023). "A Galactic Eclipse: The Small Magellanic Cloud is Forming Stars in Two, Superimposed Systems". The Astrophysical Journal. 962 (2): 120. arXiv:2312.07750. Bibcode:2024ApJ...962..120M. doi:10.3847/1538-4357/ad1591.

External links edit

 
Wikimedia Commons has media related to Small Magellanic Cloud.
  • NASA Extragalactic Database entry on the SMC
  • SEDS entry on the SMC
  • SMC at ESA/Hubble 2007-09-27 at the Wayback Machine
  • Astronomy Picture of the Day 2010 January 7 The Tail of the Small Magellanic Cloud - Likely stripped from the galaxy by gravitational tides, the tail contains mostly gas, dust, and newly formed stars.


January 01, 1970
small, magellanic, cloud, dwarf, galaxy, near, milky, classified, dwarf, irregular, galaxy, isophotal, diameter, about, kiloparsecs, light, years, contains, several, hundred, million, stars, total, mass, approximately, billion, solar, masses, distance, about, . The Small Magellanic Cloud SMC is a dwarf galaxy near the Milky Way 5 Classified as a dwarf irregular galaxy the SMC has a D25 isophotal diameter of about 5 78 kiloparsecs 18 900 light years 1 3 and contains several hundred million stars 5 It has a total mass of approximately 7 billion solar masses 6 At a distance of about 200 000 light years the SMC is among the nearest intergalactic neighbors of the Milky Way and is one of the most distant objects visible to the naked eye SMCThe Small Magellanic Cloud Source Digitized Sky Survey 2 Observation data J2000 epoch ConstellationTucana and HydrusRight ascension00h 52m 44 8s 1 Declination 72 49 43 1 Redshift0 000527 1 Distance203 7 1 5 kly 62 44 0 47 kpc 2 Apparent magnitude V 2 7 1 CharacteristicsTypeSB s m pec 1 Number of stars3 billion 4 Size5 78 kiloparsecs 18 900 light years 1 diameter 25 0 mag arcsec2 B band isophote 3 Apparent size V 5 20 3 5 1 Notable featuresCompanion dwarf to theMilky WayOther designationsSMC 1 NGC 292 1 PGC 3085 1 Nubecula Minor 1 The SMC is visible from the entire Southern Hemisphere and can be fully glimpsed low above the southern horizon from latitudes south of about 15 north The galaxy is located across the constellation of Tucana and part of Hydrus appearing as a faint hazy patch resembling a detached piece of the Milky Way The SMC has an average apparent diameter of about 4 2 8 times the Moon s and thus covers an area of about 14 square degrees 70 times the Moon s Since its surface brightness is very low this deep sky object is best seen on clear moonless nights and away from city lights The SMC forms a pair with the Large Magellanic Cloud LMC which lies 20 to the east and like the LMC is a member of the Local Group It is currently a satellite of the Milky Way but is likely a former satellite of the LMC Contents 1 Observation history 2 Features 3 X ray sources 4 Mini Magellanic Cloud MMC 5 See also 6 References 7 External linksObservation history edit nbsp Panoramic Large and Small Magellanic Clouds as seen from ESO s VLT observation site The galaxies are on the left side of the image nbsp Constellation of Tucana the SMC is the green shape at the south bottom of picture In the southern hemisphere the Magellanic clouds have long been included in the lore of native inhabitants including south sea islanders and indigenous Australians Persian astronomer Al Sufi mentions them in his Book of Fixed Stars repeating a quote by the polymath Ibn Qutaybah but had not observed them himself European sailors may have first noticed the clouds during the Middle Ages when they were used for navigation Portuguese and Dutch sailors called them the Cape Clouds a name that was retained for several centuries During the circumnavigation of the Earth by Ferdinand Magellan in 1519 1522 they were described by Antonio Pigafetta as dim clusters of stars 7 In Johann Bayer s celestial atlas Uranometria published in 1603 he named the smaller cloud Nubecula Minor 8 In Latin Nubecula means a little cloud 9 nbsp Small Magellanic Cloud as photographed by an amateur astronomer Unrelated stars have been edited out Between 1834 and 1838 John Frederick William Herschel made observations of the southern skies with his 14 inch 36 cm reflector from the Royal Observatory While observing the Nubecula Minor he described it as a cloudy mass of light with an oval shape and a bright center Within the area of this cloud he catalogued a concentration of 37 nebulae and clusters 10 In 1891 Harvard College Observatory opened an observing station at Arequipa in Peru Between 1893 and 1906 under the direction of Solon Bailey the 24 inch 610 mm telescope at this site was used to survey photographically both the Large and Small Magellanic Clouds 11 Henrietta Swan Leavitt an astronomer at the Harvard College Observatory used the plates from Arequipa to study the variations in relative luminosity of stars in the SMC In 1908 the results of her study were published which showed that a type of variable star called a cluster variable later called a Cepheid variable after the prototype star Delta Cephei showed a definite relationship between the variability period and the star s apparent brightness Leavitt realized that since all the stars in the SMC are roughly the same distance from Earth this result implied that there is similar relationship between period and absolute brightness 12 This important period luminosity relation allowed the distance to any other cepheid variable to be estimated in terms of the distance to the SMC 13 She hoped a few Cepheid variables could be found close enough to Earth so that their parallax and hence distance from Earth could be measured This soon happened allowing Cepheid variables to be used as standard candles facilitating many astronomical discoveries 14 Using this period luminosity relation in 1913 the distance to the SMC was first estimated by Ejnar Hertzsprung First he measured thirteen nearby cepheid variables to find the absolute magnitude of a variable with a period of one day By comparing this to the periodicity of the variables as measured by Leavitt he was able to estimate a distance of 10 000 parsecs 30 000 light years between the Sun and the SMC 15 This later proved to be a gross underestimate of the true distance but it did demonstrate the potential usefulness of this technique 16 Announced in 2006 measurements with the Hubble Space Telescope suggest the Large and Small Magellanic Clouds may be moving too fast to be orbiting the Milky Way 17 Features edit nbsp VISTA s view of the Small Magellanic Cloud 47 Tucanae NGC 104 is visible to the right of the Small Magellanic Cloud The SMC contains a central bar structure and astronomers speculate that it was once a barred spiral galaxy that was disrupted by the Milky Way to become somewhat irregular 18 There is a bridge of gas connecting the Small Magellanic Cloud with the Large Magellanic Cloud LMC which is evidence of tidal interaction between the galaxies 19 This bridge of gas is a star forming site 20 The Magellanic Clouds have a common envelope of neutral hydrogen indicating they have been gravitationally bound for a long time In 2017 using the Dark Energy Survey plus MagLiteS data a stellar over density associated with the Small Magellanic Cloud was discovered which is probably the result of interactions between the SMC and LMC 21 nbsp The Small Magellanic Cloud pictured by the Hubble Space Telescope 22 X ray sources editThe Small Magellanic Cloud contains a large and active population of X ray binaries Recent star formation has led to a large population of massive stars and high mass X ray binaries HMXBs which are the relics of the short lived upper end of the initial mass function The young stellar population and the majority of the known X ray binaries are concentrated in the SMC s Bar HMXB pulsars are rotating neutron stars in binary systems with Be type spectral type 09 B2 luminosity classes V III or supergiant stellar companions Most HMXBs are of the Be type which account for 70 in the Milky Way and 98 in the SMC 23 The Be star equatorial disk provides a reservoir of matter that can be accreted onto the neutron star during periastron passage most known systems have large orbital eccentricity or during large scale disk ejection episodes This scenario leads to strings of X ray outbursts with typical X ray luminosities Lx 1036 1037 erg s spaced at the orbital period plus infrequent giant outbursts of greater duration and luminosity 24 Monitoring surveys of the SMC performed with NASA s Rossi X ray Timing Explorer RXTE 25 see X ray pulsars in outburst at more than 1036 erg s and have counted 50 by the end of 2008 The ROSAT and ASCA missions detected many faint X ray point sources 26 but the typical positional uncertainties frequently made positive identification difficult Recent studies using XMM Newton 27 and Chandra 28 have now cataloged several hundred X ray sources in the direction of the SMC of which perhaps half are considered likely HMXBs and the remainder a mix of foreground stars and background AGN No X rays above background were observed from the Magellanic Clouds during the September 20 1966 Nike Tomahawk flight 29 Balloon observation from Mildura Australia on October 24 1967 of the SMC set an upper limit of X ray detection 30 An X ray astronomy instrument was carried aboard a Thor missile launched from Johnston Atoll on September 24 1970 at 12 54 UTC for altitudes above 300 km to search for the Small Magellanic Cloud 31 The SMC was detected with an X ray luminosity of 5 1038 erg s in the range 1 5 12 keV and 2 5 1039 erg s in the range 5 50 keV for an apparently extended source 31 The fourth Uhuru catalog lists an early X ray source within the constellation Tucana 4U 0115 73 3U 0115 73 2A 0116 737 SMC X 1 32 Uhuru observed the SMC on January 1 12 13 16 and 17 1971 and detected one source located at 01149 7342 which was then designated SMC X 1 33 Some X ray counts were also received on January 14 15 18 and 19 1971 34 The third Ariel 5 catalog 3A also contains this early X ray source within Tucana 3A 0116 736 2A 0116 737 SMC X 1 35 The SMC X 1 a HMXRB is at J2000 right ascension RA 01h 15m 14s declination Dec 73 42 22 Two additional sources detected and listed in 3A include SMC X 2 at 3A 0042 738 and SMC X 3 at 3A 0049 726 35 Mini Magellanic Cloud MMC editIt has been proposed by astrophysicists D S Mathewson V L Ford and N Visvanathan that the SMC may in fact be split in two with a smaller section of this galaxy behind the main part of the SMC as seen from Earth perspective and separated by about 30 000 ly They suggest the reason for this is due to a past interaction with the LMC that split the SMC and that the two sections are still moving apart They dubbed this smaller remnant the Mini Magellanic Cloud 36 37 In 2023 it was reported that the SMC is indeed two separate structures with distinct stellar and gaseous chemical compositions separated by around 5 kiloparsecs 38 See also edit nbsp Stars portal Large Magellanic Cloud Magellanic Clouds Objects within the Small Magellanic Cloud NGC 265 NGC 290 NGC 346 NGC 602References edit a b c d e f g h i j k l NASA IPAC Extragalactic Database Results for Small Magellanic Cloud Retrieved 2006 12 01 Graczyk Dariusz Pietrzynski Grzegorz Thompson Ian B Gieren Wolfgang Zgirski Bartlomiej Villanova Sandro Gorski Marek Wielgorski Piotr Karczmarek Paulina Narloch Weronika Pilecki Bogumil Taormina Monica Smolec Radoslaw Suchomska Ksenia Gallenne Alexandre Nardetto Nicolas Storm Jesper Kudritzki Rolf Peter Kaluszynski Mikolaj Pych Wojciech 2020 A Distance Determination to the Small Magellanic Cloud with an Accuracy of Better than Two Percent Based on Late type Eclipsing Binary Stars The Astrophysical Journal 904 1 13 arXiv 2010 08754 Bibcode 2020ApJ 904 13G doi 10 3847 1538 4357 abbb2b S2CID 224706414 a b De Vaucouleurs Gerard De Vaucouleurs Antoinette Corwin Herold G Buta Ronald J Paturel Georges Fouque Pascal 1991 Third Reference Catalogue of Bright Galaxies Bibcode 1991rc3 book D Jonathan Powell 17 September 2018 Rare Astronomical Sights and Sounds Springer ISBN 978 3 319 97701 0 a b Nemiroff R Bonnell J eds 2006 06 17 The Small Cloud of Magellan Astronomy Picture of the Day NASA Retrieved 2008 07 07 Bekki Kenji Stanimirovic Snezana 2009 05 01 The total mass and dark halo properties of the Small Magellanic Cloud Monthly Notices of the Royal Astronomical Society 395 1 Oxford University Press OUP 342 350 arXiv 0807 2102 Bibcode 2009MNRAS 395 342B doi 10 1111 j 1365 2966 2009 14514 x ISSN 0035 8711 S2CID 18268139 Westerlund Bengt E 1997 The Magellanic Clouds Cambridge University Press ISBN 978 0 521 48070 3 O Meara Stephen James 2002 The Caldwell Objects Cambridge University Press ISBN 978 0 521 82796 6 Lewis Charlton Thomas Kingery Hugh Macmaster 1918 An elementary Latin dictionary American Book Company ISBN 978 0 19 910205 1 Herschel John Frederick William 1849 Outlines of Astronomy Philadelphia Lea amp Blanchard ISBN 978 0 665 18744 5 Longair Malcolm S 2006 The Cosmic Century A History of Astrophysics and Cosmology Cambridge University Press ISBN 978 0 521 47436 8 Leavitt Henrietta S 1908 1777 variables in the Magellanic Clouds Annals of Harvard College Observatory 60 87 108 Bibcode 1908AnHar 60 87L Aparicio Antonio Herrero Artemio Sanchez Francisco 1998 Stellar Astrophysics for the Local Group Cambridge University Press ISBN 978 0 521 56327 7 Fernie J D December 1969 The Period Luminosity Relation A Historical Review Publications of the Astronomical Society of the Pacific 81 483 707 Bibcode 1969PASP 81 707F doi 10 1086 128847 Gribbin John R 1999 The Birth of Time How Astronomers Measured the Age of the Universe Yale University Press ISBN 978 0 300 08346 0 Hoffleit Dorrit 1992 The Selector of Highlights A Brief Biographical Sketch of Harlow Shapley The Journal of the American Association of Variable Star Observers 21 2 151 156 Bibcode 1992JAVSO 21 151H Press release Magellanic Clouds May Be Just Passing Through Harvard University January 9 2007 Small Magellanic Cloud NASA IPAC Archived from the original on 2015 11 07 Retrieved 2008 07 07 Mathewson DS Ford VL 1984 Structure and Evolution of the Magellanic Clouds IAU Symposium 108 125 Heydari Malayeri M Meynadier F Charmandaris V Deharveng L et al 2003 The stellar environment of SMC N81 Astron Astrophys 411 3 427 436 arXiv astro ph 0309126 Bibcode 2003A amp A 411 427H doi 10 1051 0004 6361 20031360 S2CID 8240730 Adriano Pieres et al 2017 A stellar over density associated with the Small Magellanic Cloud Monthly Notices of the Royal Astronomical Society 468 2 1349 1360 arXiv 1612 03938 Bibcode 2017MNRAS 468 1349P doi 10 1093 mnras stx507 Head in the Clouds Retrieved 2023 08 24 Coe et al 2005 Negueruela 1998 for a review Laycock et al 2005 Galache et al 2008 Haberl amp Sasaki 2000 Haberl et al 2008 Haberl amp Pietsch 2004 Antoniou et al 2009 Edge et al 2004 and Laycock et al 2010 Chodil G Mark H Rodrigues R Seward FD et al Oct 1967 X Ray Intensities and Spectra from Several Cosmic Sources Astrophys J 150 10 57 65 Bibcode 1967ApJ 150 57C doi 10 1086 149312 Lewin WHG Clark GW Smith WB 1968 Search for X rays from the Large and Small Magellanic Clouds Nature 220 5164 249 250 Bibcode 1968Natur 220 249L doi 10 1038 220249b0 S2CID 4187949 a b Price RE Groves DJ Rodrigues RM Seward FD et al Aug 1971 X Rays from the Magellanic Clouds Astrophys J 168 8 L7 9 Bibcode 1971ApJ 168L 7P doi 10 1086 180773 Forman W Jones C Cominsky L Julien P et al 1978 The fourth Uhuru catalog of X ray sources Astrophys J Suppl Ser 38 357 Bibcode 1978ApJS 38 357F doi 10 1086 190561 Leong C Kellogg E Gursky H Tananbaum H et al Dec 1971 X Ray Emission from the Magellanic Clouds Observed by UHURU Astrophys J 170 12 L67 71 Bibcode 1971ApJ 170L 67L doi 10 1086 180842 Tananbaum HD 1973 UHURU Results on Galactic X ray Sources In Bradt H Giacconi R eds X and Gamma Ray Astronomy Vol 55 Dordrecht Holland International Astronomical Union pp 9 28 Bibcode 1973IAUS 55 9T doi 10 1007 978 94 010 2585 0 2 ISBN 978 90 277 0337 8 a b McHardy IM Lawrence A Pye JP Pounds KA Dec 1981 The Ariel V 3 A catalogue of X ray sources II Sources at high galactic latitude absolute value of B greater than 10 deg Monthly Notices of the Royal Astronomical Society 197 4 893 919 Bibcode 1981MNRAS 197 893M doi 10 1093 mnras 197 4 893 Mathewson D S Ford V L Visvanathan N 1986 The structure of the Small Magellanic Cloud The Astrophysical Journal 301 664 Bibcode 1986ApJ 301 664M doi 10 1086 163932 ISSN 0004 637X Crowl Hugh H et al 2001 The Line of Sight Depth of Populous Clusters in the Small Magellanic Cloud The Astronomical Journal 122 1 220 231 arXiv astro ph 0104227v1 Bibcode 2001AJ 122 220C doi 10 1086 321128 ISSN 0004 6256 S2CID 45263795 Murray Claire E Hasselquist Sten Peek Joshua E G Christina Willecke Lindberg Almeida Andres Choi Yumi Craig Jessica E M Denes Helga Dickey John M Di Teodoro Enrico M Federrath Christoph Gerrard Isabella A Gibson Steven J Leahy Denis Lee Min Young Lynn Callum Yik Ki Ma Marchal Antoine McClure Griffiths N M Nidever David Nguyen Hiep Pingel Nickolas M Tarantino Elizabeth Uscanga Lucero van Loon Jacco Th 2023 A Galactic Eclipse The Small Magellanic Cloud is Forming Stars in Two Superimposed Systems The Astrophysical Journal 962 2 120 arXiv 2312 07750 Bibcode 2024ApJ 962 120M doi 10 3847 1538 4357 ad1591 External links edit nbsp Wikimedia Commons has media related to Small Magellanic Cloud NASA Extragalactic Database entry on the SMC SEDS entry on the SMC SMC at ESA Hubble Archived 2007 09 27 at the Wayback Machine Astronomy Picture of the Day 2010 January 7 The Tail of the Small Magellanic Cloud Likely stripped from the galaxy by gravitational tides the tail contains mostly gas dust and newly formed stars Retrieved from https en wikipedia org w index php title Small Magellanic Cloud amp oldid 1222258015, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.