Large Magellanic Cloud Explained

Large Magellanic Cloud
Epoch:J2000
Type:SB(s)m[1]
Dist Ly:49.97kpc[2]
Appmag V:0.13
Size V:10.75° × 9.17°
Stars:20 billion[3]
Mass: (excluding dark matter), [4] (including dark matter).
Constellation Name:Dorado/Mensa
Size:
(diameter; 25.0 mag/arcsec2 B-band isophote)[5]
Names:LMC, ESO 56- G 115, PGC 17223, Nubecula Major[6]

The Large Magellanic Cloud (LMC) is a dwarf galaxy and satellite galaxy of the Milky Way.[7] At a distance of around 50kpc,[2] [8] [9] the LMC is the second- or third-closest galaxy to the Milky Way, after the Sagittarius Dwarf Spheroidal (away) and the possible dwarf irregular galaxy called the Canis Major Overdensity. Based on the D25 isophote at the B-band (445 nm wavelength of light), the Large Magellanic Cloud is about 9.86abbr=offNaNabbr=off across. It is roughly one-hundredth the mass of the Milky Way[10] and is the fourth-largest galaxy in the Local Group, after the Andromeda Galaxy (M31), the Milky Way, and the Triangulum Galaxy (M33).

The LMC is classified as a Magellanic spiral.[11] It contains a stellar bar that is geometrically off-center, suggesting that it was once a barred dwarf spiral galaxy before its spiral arms were disrupted, likely by tidal interactions from the nearby Small Magellanic Cloud (SMC) and the Milky Way's gravity.[12] The LMC is predicted to merge with the Milky Way in approximately 2.4 billion years.[13]

With a declination of about −70°, the LMC is visible as a faint "cloud" from the southern hemisphere of the Earth and from as far north as 20° N. It straddles the constellations Dorado and Mensa and has an apparent length of about 10° to the naked eye, 20 times the Moon's diameter, from dark sites away from light pollution.[14]

History of observation

Both the Large and Small Magellanic Clouds have been easily visible for southern nighttime observers well back into prehistory. It has been claimed that the first known written mention of the Large Magellanic Cloud was by the Persian astronomer 'Abd al-Rahman al-Sufi Shirazi (later known in Europe as "Azophi"), which he referred to as Al Bakr, the White Ox, in his Book of Fixed Stars around 964 AD.[15] [16] However, this seems to be a misunderstanding of a reference to some stars south of Canopus which he admits he has not seen.[17] [18]

The first confirmed recorded observation was in 1503–1504 by Amerigo Vespucci in a letter about his third voyage. He mentioned "three Canopes, two bright and one obscure"; "bright" refers to the two Magellanic Clouds, and "obscure" refers to the Coalsack.[19]

Ferdinand Magellan sighted the LMC on his voyage in 1519 and his writings brought it into common Western knowledge. The galaxy now bears his name.The galaxy and southern end of Dorado are in the current epoch at opposition on about 5 December when thus visible from sunset to sunrise from equatorial points such as Ecuador, the Congos, Uganda, Kenya and Indonesia and for part of the night in nearby months. Above about 28° south, such as most of Australia and South Africa, the galaxy is always sufficiently above the horizon to be considered properly circumpolar, thus during spring and autumn the cloud is also visible much of the night, and the height of winter in June nearly coincides with closest proximity to the Sun's apparent position.

Measurements with the Hubble Space Telescope, announced in 2006, suggest the Large and Small Magellanic Clouds may be moving too quickly to be orbiting the Milky Way.[20]

Astronomers discovered a new black hole inside the Large Magellanic Cloud in November 2021 using the European Southern Observatory's Very Large Telescope in Chile. Astronomers claim its gravity is influenced by a nearby star, which is about five times the mass of the Sun.[21]

Geometry

The Large Magellanic Cloud has a prominent central bar and spiral arm.[22] The central bar seems to be warped so that the east and west ends are nearer the Milky Way than the middle.[23] In 2014, measurements from the Hubble Space Telescope made it possible to determine a rotation period of 250 million years.[24]

The LMC was long considered to be a planar galaxy that could be assumed to lie at a single distance from the Solar System. However, in 1986, Caldwell and Coulson[25] found that field Cepheid variables in the northeast lie closer to the Milky Way than those in the southwest. From 2001 to 2002 this inclined geometry was confirmed by the same means,[26] by core helium-burning red clump stars,[27] and by the tip of the red giant branch.[28] All three papers find an inclination of 35°, where a face-on galaxy has an inclination of 0°. Further work on the structure of the LMC using the kinematics of carbon stars showed that the LMC's disk is both thick and flared,[29] [30] likely due to interactions with the SMC.[30] Regarding the distribution of star clusters in the LMC, Schommer et al.[31] measured velocities for 80 clusters and found that the LMC's cluster system has kinematics consistent with the clusters moving in a disk-like distribution. These results were confirmed by Grocholski et al.,[32] who calculated distances to a sample of clusters and showed that the cluster system is distributed in the same plane as the field stars.

Distance

Distance to the LMC has been calculated using standard candles; Cepheid variables are one of the most popular. These have been shown to have a relationship between their absolute luminosity and the period over which their brightness varies. However the variable of metallicity may also need to be taken as a component of this as consensus is this likely affects their period-luminosity relations. Unfortunately, those in the Milky Way typically used to calibrate the relation are more metal-rich than those found in the LMC.[33]

Modern 8-meter-class optical telescopes have discovered eclipsing binaries throughout the Local Group. Parameters of these systems can be measured without mass or compositional assumptions. The light echoes of supernova 1987A are also geometric measurements, without any stellar models or assumptions.

In 2006, the Cepheid absolute luminosity was re-calibrated using Cepheid variables in the galaxy Messier 106 that cover a range of metallicities.[34] Using this improved calibration, they find an absolute distance modulus of

(m-M)0=18.41

, or 48kpc. This distance has been confirmed by other authors.[8] [9]

By cross-correlating different measurement methods, one can bound the distance; the residual errors are now less than the estimated size parameters of the LMC.

The results of a study using late-type eclipsing binaries to determine the distance more accurately was published in the scientific journal Nature in March 2013. A distance of 49.97kpc with an accuracy of 2.2% was obtained.[2]

Features

Like many irregular galaxies, the LMC is rich in gas and dust, and is currently undergoing vigorous star formation activity.[35] It holds the Tarantula Nebula, the most active star-forming region in the Local Group.

The LMC has a wide range of galactic objects and phenomena that make it known as an "astronomical treasure-house, a great celestial laboratory for the study of the growth and evolution of the stars", per Robert Burnham Jr.[36] Surveys of the galaxy have found roughly 60 globular clusters, 400 planetary nebulae and 700 open clusters, along with hundreds of thousands of giant and supergiant stars.[37] Supernova 1987A—the nearest supernova in recent years—was in the Large Magellanic Cloud. The Lionel-Murphy SNR (N86) nitrogen-abundant supernova remnant was named by astronomers at the Australian National University's Mount Stromlo Observatory, acknowledging Australian High Court Justice Lionel Murphy's interest in science and its perceived resemblance to his large nose.[38]

A bridge of gas connects the Small Magellanic Cloud (SMC) with the LMC, which evinces tidal interaction between the galaxies.[39] The Magellanic Clouds have a common envelope of neutral hydrogen, indicating that they have been gravitationally bound for a long time. This bridge of gas is a star-forming site.[40]

X-ray sources

No X-rays above background were detected from either cloud during the September 20, 1966, Nike-Tomahawk rocket flight nor that of two days later.[41] The second took off from Johnston Atoll at 17:13 UTC and reached an apogee of, with spin-stabilization at 5.6 rps.[42] The LMC was not detected in the X-ray range 8–80 keV.

Another was launched from same atoll at 11:32 UTC on October 29, 1968, to scan the LMC for X-rays. The first discrete X-ray source in Dorado was at RA Dec,[43] [44] and it was the Large Magellanic Cloud.[45] This X-ray source extended over about 12° and is consistent with the Cloud. Its emission rate between 1.5–10.5 keV for a distance of 50 kpc is /s. An X-ray astronomy instrument was carried aboard a Thor missile launched from the same atoll on September 24, 1970, at 12:54 UTC and altitudes above, to search for the Small Magellanic Cloud and to extend observation of the LMC.[46] The source in the LMC appeared extended and contained star ε Dor. The X-ray luminosity (Lx) over the range 1.5–12 keV was .[46]

The Large Magellanic Cloud (LMC) appears in the constellations Mensa and Dorado. LMC X-1 (the first X-ray source in the LMC) is at RA Dec, and is a high-mass X-ray binary (star system) source (HMXB).[47] Of the first five luminous LMC X-ray binaries: LMC X-1, X-2, X-3, X-4 and A 0538–66 (detected by Ariel 5 at A 0538–66), LMC X-2 is the one that is a bright low-mass X-ray binary system (LMXB) in the LMC.[48]

DEM L316 in the Cloud consists of two supernova remnants.[49] Chandra X-ray spectra show that the hot gas shell on the upper left has an abundance of iron. This implies that the upper-left SNR is the product of a Type Ia supernova; much lower such abundance in the lower remnant belies a Type II supernova.[49]

A 16 ms X-ray pulsar is associated with SNR 0538-69.1.[50] SNR 0540-697 was resolved using ROSAT.[51]

External links

Notes and References

  1. Web site: NASA/IPAC Extragalactic Database. Results for Large Magellanic Cloud. 29 July 2022.
  2. Pietrzyński. G. D. Graczyk . W. Gieren . I. B. Thompson . B. Pilecki . A. Udalski . I. Soszyński . etal . An eclipsing-binary distance to the Large Magellanic Cloud accurate to two per cent. Nature. 7 March 2013. 495. 7439. 76–79. 10.1038/nature11878. 23467166. 1303.2063 . 2013Natur.495...76P . 4417699.
  3. Book: Steven J. Dick . 21 March 2019 . Classifying the Cosmos: How We Can Make Sense of the Celestial Landscape . Springer . 978-3-03-010380-4 .
  4. The total mass of the Large Magellanic Cloud from its perturbation on the Orphan stream . Monthly Notices of the Royal Astronomical Society: Letters . 487 . 2 . 2685–2700 . Erkal . Denis . 2019 . 10.1093/mnras/stz1371 . free . 1812.08192 .
  5. Book: Third Reference Catalogue of Bright Galaxies . 1991rc3..book.....D . 1991 . De Vaucouleurs . Gerard . De Vaucouleurs . Antoinette . Corwin . Herold G. . Buta . Ronald J. . Paturel . Georges . Fouque . Pascal .
  6. Astronomical Society of the Pacific Leaflets, The Magellanic Clouds. Astronomical Society of the Pacific Leaflets. Buscombe, William. 7. 302. 9. 1954. 1954ASPL....7....9B.
  7. 2009MNRAS.392L..21S . Implications of recent measurements of the Milky Way rotation for the orbit of the Large Magellanic Cloud . Monthly Notices of the Royal Astronomical Society: Letters . 392 . 1 . L21–L25 . Shattow . Genevieve . Loeb . Abraham . 2009 . 10.1111/j.1745-3933.2008.00573.x . free . 0808.0104. 854729 .
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