Messier 56

Messier 56 (also known as M56 or NGC 6779) is a globular cluster in the constellation Lyra. It was discovered by Charles Messier on January 19, 1779. The cluster is located almost midway along an imaginary line between Albireo (β Cygni) and Sulafat (γ Lyrae). It is a challenge to find with large (50–80 mm) binoculars, appearing as a slightly fuzzy star.[8] The cluster can be resolved using a telescope with an aperture of 8 in (20 cm) or larger.[9]

Messier 56
Messier 56 by Hubble Space Telescope. 3.6′ view
Credit: NASA/STScI/WikiSky
Observation data (J2000 epoch)
ClassX[1]
ConstellationLyra
Right ascension 19h 16m 35.57s[2]
Declination+30° 11 00.5[2]
Distance32.9 kly (10.1 kpc)[3]
Apparent magnitude (V)+8.3
Apparent dimensions (V)8′.8
Physical characteristics
Mass2.30×105[4] M
Radius42 ly[5]
Metallicity = –2.00[6] dex
Estimated age13.70 Gyr[6]
Other designationsM56, NGC 6779, GCl 110, C 1914+300[7]

M56 is at a distance of about 32,900[3] light-years from Earth and measures roughly 84 light-years across, with a combined mass some 230,000[4] times that of the Sun. It is about 31–32 kly (9.5–9.8 kpc) from the Galactic Center and 4.8 kly (1.5 kpc) above the galactic plane.[10] This cluster has an estimated age of 13.70 billion years and is following a retrograde orbit through the Milky Way. The properties of this cluster suggest that it may have been acquired during the merger of a dwarf galaxy, of which Omega Centauri forms the surviving nucleus. For Messier 56, the abundance of elements other than hydrogen and helium, what astronomers term the metallicity, has a very low value of [Fe/H] = –2.00 dex. This is equivalent to 1% of the abundance in the Sun.[6]

The brightest stars in M56 are of 13th magnitude, while it contains only about a dozen known variable stars, such as V6 (RV Tauri star; period: 90 days) or V1 (Cepheid: 1.510 days);[11] other variable stars are V2 (irregular) and V3 (semiregular). In 2000, a diffuse X-ray emission was tentatively identified coming from the vicinity of the cluster. This is most likely interstellar medium that has been heated by the passage of the cluster through the galactic halo. The relative velocity of the cluster is about 177 km s−1, which is sufficient to heat the medium in its wake to a temperature of 940,000 K.[12]

M56 is part of the Gaia Sausage, the hypothesised remains of a merged dwarf galaxy.[13]

gollark: You can postpone mine. I like game theory.
gollark: I mean, Scratch less so.
gollark: Another somewhat problematic thing with Scratch (and the government here's "micro:bits", small single board computers which connect via USB and have a 5x5 LED matrix and a bunch of pins, and which they gave out to all students in my year a while back) is that they end up implying to you that you can only program things on dedicated special environments.
gollark: I think my suggested things would be more actually-useful to people.
gollark: <@241757436720054273> I guess Scratch may teach that a bit (though often you'll just be made to blindly follow a tutorial for "learn to code" stuff) but it doesn't teach it very *well* because it's generally lacking in useful constructs.

References

  1. Shapley, Harlow; Sawyer, Helen B. (August 1927), "A Classification of Globular Clusters", Harvard College Observatory Bulletin, 849 (849): 11–14, Bibcode:1927BHarO.849...11S.
  2. Goldsbury, Ryan; et al. (December 2010), "The ACS Survey of Galactic Globular Clusters. X. New Determinations of Centers for 65 Clusters", The Astronomical Journal, 140 (6): 1830–1837, arXiv:1008.2755, Bibcode:2010AJ....140.1830G, doi:10.1088/0004-6256/140/6/1830.
  3. Ivanov, Valentin D.; et al. (2000). "Near Infrared Photometry of Galactic Globular Clusters M56 and M15. Extending the Red Giant Branch vs. Metallicity Calibration Towards Metal Poor Systems". arXiv:astro-ph/0002118.
  4. Boyles, J.; et al. (November 2011), "Young Radio Pulsars in Galactic Globular Clusters", The Astrophysical Journal, 742 (1): 51, arXiv:1108.4402, Bibcode:2011ApJ...742...51B, doi:10.1088/0004-637X/742/1/51.
  5. From trigonometry: radius = distance × sin( diameter_angle / 2 ) = 32,900 × sin(8.8′/2) = 42.1 ly.
  6. Forbes, Duncan A.; Bridges, Terry (May 2010), "Accreted versus in situ Milky Way globular clusters", Monthly Notices of the Royal Astronomical Society, 404 (3): 1203–1214, arXiv:1001.4289, Bibcode:2010MNRAS.404.1203F, doi:10.1111/j.1365-2966.2010.16373.x
  7. "M 56". SIMBAD. Centre de données astronomiques de Strasbourg. Retrieved 2006-11-16.
  8. Thompson, Robert Bruce; Thompson, Barbara Fritchman (2007), Illustrated guide to astronomical wonders, DIY science, O'Reilly Media, Inc., p. 311, ISBN 978-0-596-52685-6
  9. Inglis, Mike (2004), Astronomy of the Milky Way: Observer's guide to the northern sky, Astronomy of the Milky Way, 1, Springer, p. 90, Bibcode:2003amwn.book.....I, ISBN 978-1-85233-709-4
  10. Bica, E.; et al. (April 2006), "Globular cluster system and Milky Way properties revisited", Astronomy and Astrophysics, 450 (1): 105–115, arXiv:astro-ph/0511788, Bibcode:2006A&A...450..105B, doi:10.1051/0004-6361:20054351
  11. Pietrukowicz, P.; et al. (June 2008), "CURiuos Variables Experiment (CURVE): Variable Stars in the Metal-Poor Globular Cluster M56", Acta Astronomica, 58: 121–130, arXiv:0806.1515, Bibcode:2008AcA....58..121P
  12. Hopwood, M. E. L.; et al. (July 2000), "A possible detection of diffuse extended X-ray emission in the environment of the globular cluster NGC 6779", Monthly Notices of the Royal Astronomical Society, 316 (1): L5–L8, Bibcode:2000MNRAS.316L...5H, doi:10.1046/j.1365-8711.2000.03717.x
  13. Myeong, G. C; Evans, N. W; Belokurov, V; Sanders, J. L; Koposov, S. E (2018). "The Sausage Globular Clusters". The Astrophysical Journal. 863 (2): L28. arXiv:1805.00453. Bibcode:2018ApJ...863L..28M. doi:10.3847/2041-8213/aad7f7.


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