Sagittarius B2

Sagittarius B2 (Sgr B2) is a giant molecular cloud of gas and dust that is located about 120 parsecs (390 ly) from the center of the Milky Way. This complex is the largest molecular cloud in the vicinity of the core and one of the largest in the galaxy, spanning a region about 45 parsecs (150 ly) across.^[2] The total mass of Sgr B2 is about 3 million times the mass of the Sun.^[3] The mean hydrogen density within the cloud is 3000 atoms per cm³, which is about 20–40 times denser than a typical molecular cloud.^[4]

Sagittarius B2

Molecular cloud
Giant molecular cloud
Observation data: J2000.0[1] epoch
Right ascension	17h 47m 20.4s[1]
Declination	−28° 23′ 07″[1]
Constellation	Sagittarius
Physical characteristics
Radius	23 pc
Designations	Sagittarius B2, Sgr B2
See also: Lists of nebulae

The internal structure of this cloud is complex, with varying densities and temperatures. The cloud is divided into three main cores, designated north (N), middle or main (M) and south (S) respectively. Thus Sgr B2(N) represents the north core. The sites Sgr B2(M) and Sgr B2(N) are sites of prolific star formation. The first 10 H II regions discovered were designated A through J.^[5] H II regions A–G, I and J lie within Sgr B2(M), while region K is in Sgr B2(N) and region H is in Sgr B2(S).^[6] The 5-parsec-wide core of the cloud is a star-forming region that is emitting about 10 million times the luminosity of the Sun.^[7]

The cloud is composed of various kinds of complex molecules, of particular interest: alcohol. The cloud contains ethanol, vinyl alcohol, and methanol. This is due to the conglomeration of atoms resulting in new molecules. The composition was discovered via spectrograph in an attempt to discover amino acids. An ester, ethyl formate, was also discovered, which is a major precursor to amino acids. This ester is also responsible for the flavour of raspberries,^[8] leading some articles on Sagittarius B2 to postulate the cloud as smelling of ‘raspberry rum’.^[9][10] Large quantities of butyronitrile (propyl cyanide) and other alkyl cyanides have also been detected as being present in the cloud.^[11]

Temperatures in the cloud vary from 300 K (27 °C) in dense star-forming regions to 40 K (−233.2 °C) in the surrounding envelope.^[12] Because the average temperature and pressure in Sgr B2 are low, chemistry based on the direct interaction of atoms is exceedingly slow. However, the Sgr B2 complex contains cold dust grains consisting of a silicon core surrounded by a mantle of water ice and various carbon compounds. The surfaces of these grains allow chemical reactions to occur by accreting molecules that can then interact with neighboring compounds. The resulting compounds can then evaporate from the surface and join the molecular cloud.^[2]

The molecular components of this cloud can be readily observed in the 10²–10³ μm range of wavelengths.^[2] About half of all the known interstellar molecules were first found near Sgr B2, and nearly every other currently known molecule has since been detected in this feature.^[13]

The European Space Agency's gamma-ray observatory INTEGRAL has observed gamma rays interacting with Sgr B2, causing X-ray emission from the molecular cloud. This energy was emitted about 350 years ago by the supermassive black hole (SMBH) at the galaxy's core, Sagittarius A*. The total luminosity from this outburst is an estimated million times stronger than the current output from Sagittarius A*.^[14][15] This conclusion was supported in 2011 by Japanese astronomers who observed the Galactic Center with the Suzaku satellite.^[16]

See also

•  Astronomy portal

• Large Molecule Heimat
• List of molecules in interstellar space

References

1. "NAME Sgr B2". SIMBAD. Centre de données astronomiques de Strasbourg. Retrieved 2014-03-14.
2. Chown, Marcus (November 27, 1999). "Star attraction". New Scientist. Retrieved 2007-10-29.
3. Solomon, P. M. (1978). Giancarlo Setti; Giovanni G. Fazio (eds.). Physics of Molecular Clouds from Millimeter Wave Length Observations. New York: Springer. ISBN 90-277-0871-1. {{cite book}}: |work= ignored (help)
4. Goldsmith, Paul F.; Lis, Dariusz C.; Hills, Richard; Lasenby, Joan (1990). "High angular resolution submillimeter observations of Sagittarius B2". Astrophysical Journal. 350: 186–194. Bibcode:1990ApJ...350..186G. doi:10.1086/168372.
5. Lis, Dariusz C.; Goldsmith, Paul F. (1990). "Modeling of the continuum and molecular line emission from the Sagittarius B2 molecular cloud". Astrophysical Journal, Part 1. 356: 195–210. Bibcode:1990ApJ...356..195L. doi:10.1086/168830.
6. Takagi, Shin-ichiro; Murakami, Hiroshi; Koyama, Katsuji (2002). "X-Ray Sources and Star Formation Activity in the Sagittarius B2 Cloud Observed with Chandra". The Astrophysical Journal. 573 (1): 275–282. arXiv:astro-ph/0203035. Bibcode:2002ApJ...573..275T. doi:10.1086/340499. S2CID 119426549.
7. Wolstencroft, Ramon D.; William Butler Burton (1988). Millimetre and Submillimetre Astronomy. Springer. ISBN 90-277-2763-5.
8. Gupta, Richa (2015-08-12). "Raspberries and Rum- Sagittarius B2". Astronaut. Archived from the original on 2022-07-18. Retrieved 2020-07-25.
9. "A raspberry flavoured galactic centre with a hint of rum". Wiley Analytical Science. doi:10.1002/sepspec.21408ezine (inactive 31 January 2024). Retrieved 2020-07-25.
10. Team, How It Works (2015-12-03). "The Milky Way smells of rum and tastes like raspberries". How It Works. Retrieved 2020-07-25.
11. Belloche, A.; Garrod, R. T.; Müller, H. S. P.; Menten, K. M.; Comito, C.; Schilke, P. (2009-05-01). "Increased complexity in interstellar chemistry: detection and chemical modeling of ethyl formate and n-propyl cyanide in Sagittarius B2(N)". Astronomy & Astrophysics. 499 (1): 215–232. arXiv:0902.4694. Bibcode:2009A&A...499..215B. doi:10.1051/0004-6361/200811550. ISSN 0004-6361. S2CID 98625608.
12. de Vicente, P.; Martin-Pintado, J.; Wilson, T. L. (March 10–15, 1996). "A Hot Ring in the SGR B2 Molecular Cloud". Proceedings Astronomical Society of the Pacific Conference Series. La Serena, Chile: Astronomical Society of the Pacific. pp. 64–67. Bibcode:1996ASPC..102...64D.
13. S. E. Cummins; R. A. Linke; P. Thaddeus (1986). "A survey of the millimeter-wave spectrum of Sagittarius B2". Astrophysical Journal Supplement Series. 60: 819–878. Bibcode:1986ApJS...60..819C. doi:10.1086/191102.
14. Staff (January 28, 2005). "Integral rolls back history of Milky Way's super-massive black hole". Hubble News Desk. Retrieved 2007-10-31.
15. M. G. Revnivtsev; et al. (2004). "Hard X-ray view of the past activity of Sgr A* in a natural Compton mirror". Astronomy and Astrophysics. 425: L49–L52. arXiv:astro-ph/0408190. Bibcode:2004A&A...425L..49R. doi:10.1051/0004-6361:200400064. S2CID 18872302.
16. M. Nobukawa; et al. (2011). "New Evidence for High Activity of the Supermassive Black Hole in our Galaxy". The Astrophysical Journal Letters. 739 (2): L52. arXiv:1109.1950. Bibcode:2011ApJ...739L..52N. doi:10.1088/2041-8205/739/2/L52. S2CID 119244398.

External links

• R. M. Gaume; et al. (October 31, 2007). "Sagittarius B1 (North)". National Radio Astronomy Observatory. Retrieved 2007-10-31.
• How Did Organic Matter Reach Earth? Cosmic Detectives Trace Origin of Complex Organic Molecules, on: SciTechDaily. September 10, 2020. Source: Tokyo University of Science: Acetonitrile found in molecular cloud Sgr B2(M) at the center of the Milky Way galaxy.