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Sagittarius Dwarf Spheroidal Galaxy

Coordinates: Sky map 18h 55m 19.5s, −30° 32′ 43″
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Sagittarius Dwarf Spheroidal Galaxy[1]
The Sagittarius Dwarf Spheroidal Galaxy in Aitoff allsky view.
Observation data (J2000 epoch)
ConstellationSagittarius
Right ascension18h 55m 19.5s[2]
Declination−30° 32′ 43″[2]
Redshift140 ± ? km/s[2]
Distance65 ± 7 kly (20 ± 2 kpc)[3][4]
Apparent magnitude (V)4.5[2]
Characteristics
TypedSph(t)[2]
Mass4*108[5] M
Apparent size (V)450′.0 × 216′.0[2]
Notable featuresHeading for a collision
with the Milky Way
Other designations
Sag DEG,[6] Sgr dSph,[2] Sagittarius Dwarf Spheroidal,[2] Sgr I Dwarf[2]

The Sagittarius Dwarf Spheroidal Galaxy (Sgr dSph), also known as the Sagittarius Dwarf Elliptical Galaxy (Sgr dE or Sag DEG), is an elliptical loop-shaped satellite galaxy of the Milky Way. It contains four globular clusters, with the brightest of them – NGC 6715 (M54) – being known well before the discovery of the galaxy itself in 1994. Sgr dSph is roughly 10,000 light-years in diameter, and is currently about 70,000 light-years from Earth, travelling in a polar orbit (an orbit passing over the Milky Way's galactic poles) at a distance of about 50,000 light-years from the core of the Milky Way (about one third of the distance of the Large Magellanic Cloud). In its looping, spiraling path, it has passed through the plane of the Milky Way several times in the past.[7] In 2018 the Gaia project of the European Space Agency showed that Sgr dSph had caused perturbations in a set of stars near the Milky Way's core, causing unexpected rippling movements of the stars triggered when it sailed past the Milky Way between 300 and 900 million years ago. [8]

Features

Officially discovered in 1994, by Rodrigo Ibata, Mike Irwin, and Gerry Gilmore,[9] Sgr dSph was immediately recognized as being the nearest known neighbor to the Milky Way at the time. (Since 2003, the newly discovered Canis Major Dwarf Galaxy is considered the actual nearest neighbor.) Although it is one of the closest companion galaxies to the Milky Way, the main parent cluster is on the opposite side of the galactic core from Earth, and consequently is very faint, although covering a large area of the sky. Sgr dSph appears to be an older galaxy, with little interstellar dust and composed largely of Population II stars, older and metal-poor, as compared to the Milky Way. No neutral hydrogen gas related to Sgr dSph has been found.[10]

Further discoveries by astrophysics teams from both the University of Virginia and the University of Massachusetts Amherst, drawing upon the 2MASS Two-Micron All Sky Infrared Survey data, revealed the entire loop-shaped structure. In 2003 with the aid of infrared telescopes and super computers, Steven Majewski, Michael Skrutskie, and Martin Weinberg were able to help create a new star map, picking out the full Sagittarius Dwarf presence, position, and looping shape from the mass of background stars and finding this smaller galaxy to be at a near right angle to the plane of the Milky Way.[11]

Globular clusters

Messier 54, believed to be at the core of Sgr dSph. Greyscale image created from the HST's Advanced Camera for Surveys
Palomar 12, believed to have been captured from the Sgr dSph about 1.7 Gya

Sgr dSph has four known globular clusters with one, M 54, apparently residing at its core. It is also dynamically linked to the "young" globular Terzan 7 as well as to Terzan 8 and Arp 2.[12] Additionally, Palomar 12 is now generally thought to also be associated with Sgr dSph [13][14] as well as Whiting 1.[15][16][clarification needed]

Metallicity

Sgr dSph has multiple stellar populations, ranging in age from the oldest globular clusters (almost as old as the universe itself) to trace populations as young as several hundred million years (mya). It also exhibits an age-metallicity relationship, in that its old populations are metal poor ([Fe/H] = −1.6±0.1) while its youngest populations have super-solar abundances.[16][17]

Geometry and dynamics

Based on its current trajectory, the Sgr dSph main cluster is about to pass through the galactic disc of the Milky Way within the next hundred million years, while the extended loop-shaped ellipse is already extended around and through our local space and on through the Milky Way galactic disc, and in the process of slowly being absorbed into the larger galaxy, calculated at 10,000 times the mass of Sgr dSph. The dissipation of the Sgr dSph main cluster is and its merger with the Milky Way stream is expected to be complete within a billion years from now.[5]

At first, many astronomers thought that Sgr dSph had already reached an advanced state of destruction, so that a large part of its original matter was already mixed with that of the Milky Way. However, Sgr dSph still has coherence as a dispersed elongated ellipse, and appears to move in a roughly polar orbit around the Milky Way as close as 50,000 light-years from the galactic core. Although it may have begun as a spherical object before falling towards the Milky Way, Sgr dSph is now being torn apart by immense tidal forces over hundreds of millions of years. Numerical simulations suggest that stars ripped out from the dwarf would be spread out in a long stellar stream along its path, which were subsequently detected.

However, some astronomers contend that Sgr dSph has been in orbit around the Milky Way for some billions of years, and has already orbited it approximately ten times. Its ability to retain some coherence despite such strains would indicate an unusually high concentration of dark matter within that galaxy.

In 1999, Johnston et al. concluded that Sgr dSph has orbited the Milky Way for at least one Gya and that during that time its mass has decreased by a factor of two or three. Its orbit is found to have galactocentric distances that oscillate between ~13 and ~41 kpc with a period of 550 to 750 million years. The last perigalacticon was approximately fifty million years ago. Also in 1999, Jiang & Binney found that it may have started its infall into the Milky Way at a point more than 200 kpc away if its starting mass was as large as ~1011M.

The models of both its orbit and the Milky Way's potential field could be improved by proper motion observations of Sgr dSph's stellar debris. This issue is under intense investigation, with computational support by the MilkyWay@Home project.

A simulation published in 2011 suggested that the Milky Way may have obtained its spiral structure as a result of repeated collisions with Sgr dSph.[7]

In 2018, the Gaia project of the European Space Agency, designed primarily to investigate the origin, evolution and structure of the Milky Way, delivered the largest and most precise census of positions, velocities and other stellar properties of more than a billion stars, which showed that Sgr dSph had caused perturbations in a set of stars near the Milky Way's core, causing unexpected rippling movements of the stars triggered when it sailed past the Milky Way between 300 and 900 million years ago.[8]

A 2019 study by Melendez and co-authors concluded that Sgr dSph had a decreasing metallicity trend as a function of radius, with a larger spread in metallicity in the core relative to the outer regions. Also, they did find evidence for the first time for two distinct populations in alpha abundances as a function of metallicity.[18][19]

A 2020 study concluded that collisions between the Sagittarius Dwarf Spheroidal Galaxy and the Milky Way triggered major episodes of star formation in the latter, based on data taken from the Gaia project.[20]

See also

References

  1. ^ "Name SDG". SIMBAD. Centre de données astronomiques de Strasbourg. Retrieved 28 November 2006.
  2. ^ a b c d e f g h i "Saggitarius Dwarf Spheroidal". NASA/IPAC Extragalactic Database. Retrieved 28 November 2006.
  3. ^ Karachentsev, I. D.; Karachentseva, V. E.; Hutchmeier, W. K.; Makarov, D. I. (2004). "A Catalog of Neighboring Galaxies". The Astronomical Journal. 127 (4): 2031–2068. Bibcode:2004AJ....127.2031K. doi:10.1086/382905.
  4. ^ Karachentsev, I. D.; Kashibadze, O. G. (2006). "Masses of the local group and of the M81 group estimated from distortions in the local velocity field". Astrophysics. 49 (1): 3–18. Bibcode:2006Ap.....49....3K. doi:10.1007/s10511-006-0002-6.
  5. ^ a b A bot will complete this citation soon. Click here to jump the queue arXiv:2006.02929.
  6. ^ Sagittarius Dwarf Elliptical Galaxy / Sag DEG
  7. ^ a b "Star-Crossed: Milky Way's spiral shape may result from a smaller galaxy's impact". 15 December 2016. Archived from the original on 15 December 2016.
  8. ^ a b "A dynamically young and perturbed Milky Way disk". Nature. 19 September 2018.
  9. ^ Ibata, R.A.; Gilmore, G.; Irwin, M.J. (1994). "A dwarf satellite galaxy in Sagittarius". Nature. 370 (6486): 194. Bibcode:1994Natur.370..194I. doi:10.1038/370194a0.
  10. ^ van den Bergh, Sidney (April 2000). "Updated Information on the Local Group". Publications of the Astronomical Society of the Pacific. 112 (770): 529–536. arXiv:astro-ph/0001040. Bibcode:2000PASP..112..529V. doi:10.1086/316548.
  11. ^ Sagitarius – big (image). University of Virginia.
  12. ^ Sbordone, L.; Bonifacio, P.; Marconi, G.; Buonanno, R.; Zaggia, S. (3 July 2005). "Family ties: Abundances in Terzan 7, a Sgr dSph globular cluster". Astronomy and Astrophysics. 437 (3): 905–910. arXiv:astro-ph/0505307. Bibcode:2005A&A...437..905S. doi:10.1051/0004-6361:20042315.
  13. ^ Judith G. Cohen (2004). "Palomar 12 as a part of the Sagittarius stream: The evidence from abundance ratios". The Astronomical Journal. 127 (3): 1545–1554. arXiv:astro-ph/0311187. Bibcode:2004AJ....127.1545C. doi:10.1086/382104.
  14. ^ Sbordone; et al. (5 December 2006). "The exotic chemical composition of the Sagittarius dwarf Spheroidal galaxy". Astronomy & Astrophysics. 465 (3): 815–824. arXiv:astro-ph/0612125. Bibcode:2007yCat..34650815S. doi:10.1051/0004-6361:20066385.
  15. ^ Giovanni Carraro; Robert Zinn; Christian Moni Bidin (9 February 2007). "Whiting 1:the youngest globular cluster associated with the Sgr dSph". Astronomy & Astrophysics. 466: 181–189. arXiv:astro-ph/0702253. Bibcode:2007yCat..34660181C. doi:10.1051/0004-6361:20066825.
  16. ^ a b Geisler, Doug; Wallerstein, George; Smith, Verne V.; Casetti-Dinescu, Dana I. (September 2007). "Chemical Abundances and Kinematics in Globular Clusters and Local Group Dwarf Galaxies and Their Implications for Formation Theories of the Galactic Halo". Publications of the Astronomical Society of the Pacific. 119 (859): 939–961. arXiv:0708.0570. Bibcode:2007PASP..119..939G. doi:10.1086/521990.
  17. ^ Siegel, Michael H.; Dotter, Aaron; Majewski, Steven R.; Sarajedini, Ata; Chaboyer, Brian; Nidever, David L.; Anderson, Jay; Marín-Franch, Antonio; Rosenberg, Alfred; et al. (September 2007). "The ACS Survey of Galactic Globular Clusters: M54 and Young Populations in the Sagittarius Dwarf Spheroidal Galaxy". Astrophysical Journal Letters. 667 (1): 57–60. arXiv:0708.0027. Bibcode:2007ApJ...667L..57S. doi:10.1086/522003.
  18. ^ Melendez, Matthew; Frinchaboy, Peter M.; Donor, John; Ray, Amy. "Using The Cannon to study the chemistry of the Sagittarius dwarf galaxy" (PDF).
  19. ^ "Matthew Melendez explores a small galaxy that is falling into our own". TCU Astronomy and Physics. April 13, 2019 – via YouTube.
  20. ^ Ruiz-Lara, Tomás; Gallart, Carme; Bernard, Edouard J.; Cassisi, Santi (2020). "The recurrent impact of the Sagittarius dwarf on the star formation history of the Milky Way". Nature Astronomy. doi:10.1038/s41550-020-1097-0. {{cite journal}}: Cite journal requires |journal= (help)