Sh 2-185

(Redirected from IC 59)

Sh 2-185 is an H II region centered on the massive star system Gamma Cassiopeiae (γ Cas) in the northern constellation of Cassiopeia. It was included in the second Catalogue of H II Regions, published in 1959 by Stewart Sharpless.[3] Sh 2-185 is located at a distance of approximately 10,500 ly (3.23 kpc) from the Sun.[2] The region is surrounded by a dust shell,[4] and displays several infrared point sources that are a characteristics of young stellar objects.[5]

Sh 2-185
Emission nebula
H II region
IC 59 (center) and IC 63 (left) near Gamma Cassiopeiae
The brightest star is Gamma Cassiopeiae. The blue IC 59 nebula is positioned above the star and the redder IC 63 is to the left.
Observation data: J2000 epoch
Right ascension01h 00m 00s[1]
Declination+60° 59′[1]
Distance10,500 ± 2,100[2] ly
Apparent dimensions (V)[3]
ConstellationCassiopeia
See also: Lists of nebulae

This H II region includes the reflection and emission nebulae IC 59 and IC 63.[4] Both nebulae have a cometary shape, with IC 63 being the brighter of the two.[6] The difference in appearance between the two nebulae is a consequence of their physical distance from γ Cas. IC 63 displays a well-defined ionization front, while this is lacking in IC 59.[5] The nebulae are the closest photodissociation regions to the Sun.[6]

IC 59

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This nebula was discovered by German astronomer Max Wolf on December 30, 1893,[7] then added to J. L. E. Dreyer's Index Catalogue of Nebulae in 1895.[8] It spans an angular size of 10 and is visible with a small telescope.[9] From the perspective of the Earth, IC 59 is positioned in front of γ Cas, and the closest tip to the star is located at a separation of 13.5 ly (4.15 pc). It is a photodissociation region that is being sculpted by γ Cas. Light from the star is being scattered from the nebula at an angle of 17° toward the Earth.[6]

Although the tip of the nebula has been considered the closest point to γ Cas, the western concave face is where the most intense UV radiation is being received. Hence the tip may actually be further away from the star than the rest of the cloud. The warmer component of this nebula has a mean temperature of 675±49 K, while the cooler component is 150±34 K.[10]

IC 63

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IC 63 is sometimes dubbed the Ghost Nebula, or the ghost of Cassiopeia.[11] It was discovered by Max Wolf on the same night as IC 59,[7] and has since been extensively studied.[10] It spans an angular size of 10 and is visible with a small telescope.[9] From the perspective of the Earth, IC 63 is positioned behind γ Cas, and the closest tip to the star is located at a separation of 7.5 ly (2.3 pc). It is a photodissociation region that is being sculpted by γ Cas. Light from the star is being scattered from the nebula at an angle of 154° toward the Earth.[6]

There is no evidence of triggered star formation in this nebula.[5] The warmer component of this nebula has a mean temperature of 740±47 K, while the cooler component is 207±30 K.[10] The velocity distribution across the nebula varies with the distance from the star, and is consistent with it being driven by the radiation.[12] The atomic hydrogen in the PDR structure has a clumpy organization, while the tip has a ring-like structure. The entire structure seems to be moving apart and it is likely that this nebula will completely disperse within a half million years.[13]

References

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  1. ^ a b Dubout-Crillon, R. (July 1976), "H II regions of the northern Milky Way: medium-large-field photographic atlas and catalogue.", Astronomy and Astrophysics, Supplement Series, 25: 25–54, Bibcode:1976A&AS...25...25D.
  2. ^ a b Foster, T.; Brunt, C. M. (November 2015), "A CGPS Look at the Spiral Structure of the Outer Milky Way. I. Distances and Velocities to Star-forming Regions", The Astronomical Journal, 150 (5), id. 147, arXiv:1405.7003, Bibcode:2015AJ....150..147F, doi:10.1088/0004-6256/150/5/147.
  3. ^ a b Sharpless, Stewart (December 1959), "A catalogue of HII regions", Astrophysical Journal Supplement, 4: 257, Bibcode:1959ApJS....4..257S, doi:10.1086/190049.
  4. ^ a b Soam, Archana; et al. (March 2021), "Interstellar Extinction, Polarization, and Grain Alignment in the Sh 2-185 (IC 59 and IC 63) Region", The Astronomical Journal, 161 (3), id. 149, arXiv:2101.06312, Bibcode:2021AJ....161..149S, doi:10.3847/1538-3881/abdd3b.
  5. ^ a b c Karr, J. L.; et al. (February 2005), "A Multiwavelength Study of IC 63 and IC 59", The Astronomical Journal, 129 (2): 954–968, Bibcode:2005AJ....129..954K, doi:10.1086/426912.
  6. ^ a b c d Eiermann, Jacob M.; et al. (April 2024), "The 3D geometry of reflection nebulae IC 59 and IC 63 with their illuminating star gamma Cas", Monthly Notices of the Royal Astronomical Society, 529 (2): 1680–1687, arXiv:2401.06941, Bibcode:2024MNRAS.529.1680E, doi:10.1093/mnras/stae102.
  7. ^ a b Seligman, Courtney, "IC Objects: IC 50 - 99", Celestial Atlas, retrieved 2024-07-29.
  8. ^ Dreyer, J. L. E. (1895), "Index Catalogue of Nebulæ found in the years 1888 to 1894, with Notes and Corrections to the New General Catalogue", Memoirs of the Royal Astronomical Society, 51: 185, Bibcode:1895MmRAS..51..185D.
  9. ^ a b Gilmour, Jess K. (2012), The Practical Astronomer's Deep-sky Companion, Springer London, p. 37, ISBN 9781447100713.
  10. ^ a b c Andrews, H.; et al. (November 2018), "Whipping IC 63/IC 59", Astronomy & Astrophysics, 619, id. A170, Bibcode:2018A&A...619A.170A, doi:10.1051/0004-6361/201832808, hdl:1887/69564.
  11. ^ The ghost of Cassiopeia, NASA/ESA Hubble, October 25, 2018, retrieved 2024-07-03.
  12. ^ Caputo, Miranda; et al. (June 2023), "Physics and Chemistry of Radiation Driven Cloud Evolution. [C II] Kinematics of IC 59, and IC 63", The Astrophysical Journal, 950 (2), id. 140, arXiv:2305.05719, Bibcode:2023ApJ...950..140C, doi:10.3847/1538-4357/acd2d5.
  13. ^ Bonne, Lars; et al. (June 2023), "High-resolution Observations of H I in the IC 63 Reflection Nebula", The Astronomical Journal, 165 (6), id. 243, arXiv:2304.13669, Bibcode:2023AJ....165..243B, doi:10.3847/1538-3881/accf85.

Further reading

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