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NGC 300

Coordinates: Sky map 00h 54m 53.5s, −37° 41′ 04″
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(Redirected from Caldwell 70)
NGC 300
NGC 300 imaged by ESO's La Silla Observatory
Observation data (J2000 epoch)
ConstellationSculptor
Right ascension00h 54m 53.48s[1]
Declination−37° 41′ 03.8″[1]
Redshift0.000480 [1]
Heliocentric radial velocity144 ± 1 km/s[1]
Distance6.07 ± 0.23 Mly (1.86 ± 0.07 Mpc)[2][a]
Apparent magnitude (V)9.0[1]
Characteristics
TypeSA(s)d[1]
Mass(2.9 ± 0.2) × 1010 M
Size~110,000 ly (35 kpc) (estimated)[3]
Apparent size (V)21.9′ × 15.5′[1]
Other designations
ESO 295- G 020, IRAS 00525-3757, 2MASX J00545347-3741037, MCG -06-03-005, PGC 3238, Caldwell 70[1]

NGC 300 (also known as Caldwell 70 or the Sculptor Pinwheel Galaxy[4]) is a spiral galaxy in the constellation Sculptor. It was discovered on 5 August 1826 by Scottish astronomer James Dunlop.[5] It is one of the closest galaxies to the Local Group, and it most likely lies between the latter and the Sculptor Group. It is the brightest of the five main spirals in the direction of the Sculptor Group.[2] It is inclined at an angle of 42° when viewed from Earth and shares many characteristics of the Triangulum Galaxy.[6] It is 94,000 light-years in diameter, somewhat smaller than the Milky Way, and has an estimated mass of (2.9 ± 0.2) × 1010 M.[3][7]

Nearby galaxies and group information

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NGC 300 and the irregular galaxy NGC 55 have traditionally been identified as members of the Sculptor Group, a nearby group of galaxies in the constellation of the same name. However, recent distance measurements indicate that these two galaxies actually lie in the foreground.[8] It is likely that NGC 300 and NGC 55 form a gravitationally bound pair.[9]

Distance estimates

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In 1986, Allan Sandage estimated the distance to NGC 300 to be 5.41 Mly (1.66 Mpc).[10] By 1992, this had been updated to 6.9 Mly (2.1 Mpc) by Freedman et al.[2] In 2006, this was revised by Karachentsev et al. to be 7.0±0.3 Mly (2.15±0.10 Mpc).[11] At about the same time, the tip of the red giant branch (TRGB) method was used to produce an estimate of 5.9±0.4 Mly (1.82±0.13 Mpc) using edge detection and 6.1±0.4 Mly (1.87±0.12 Mpc) using maximum likelihood.[2] These results were consistent with estimates using near-infrared photometry of Cepheid variables by Gieren et al. 2005 that provided an estimate of 6.1±0.2 Mly (1.88±0.07 Mpc).[2] Combining the recent TRGB and Cepheid estimates the distance to NGC 300 is estimated at 6.07±0.23 Mly (1.86±0.07 Mpc).[a]

NGC 300-OT

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On a CCD image obtained on May 14, 2008, amateur astronomer L.A.G. Berto Monard discovered a bright optical transient (OT) in NGC 300 that is designated NGC 300-OT.[12] It is located at RA00h 54m 34.552s and DEC: −37° 38′ 31.79″[13] in a spiral arm containing active star formation.[14] Its broad-band magnitude was 14.3 in that image. An earlier image (from April 24, 2008), taken just after NGC 300 reemerged from behind the Sun, evidenced an already brightening OT at ~16.3 magnitude.[14] No brightening was detected on a February 8, 2008 image or on any earlier ones.[14] The transient's peak measured magnitude was 14.69 on May 15, 2008.[14]

At discovery, the transient had an absolute magnitude of MV ≈ −13, making it faint in comparison to a typical core-collapse supernova but bright in comparison to a classical nova.[12][14] Additionally, the photometric and spectroscopic properties of the OT imply that it is not a luminous blue variable either.[14] Since its peak, brightness dropped smoothly through September 2008 while becoming continuously redder.[14] After September 2008, brightness continued to fall at a lower rate in the optical spectrum but with strong emissions.[14] Further, the optical spectrum is mostly made up of fairly narrow Hydrogen Balmer and Ca II emission lines coupled with strong Ca II H&K absorption.[12] Research into historical Hubble images provide an accurate upper bound on the progenitor star's brightness.[12] This suggested a low-mass main sequence star as progenitor with the transient resulting from a stellar merger similar to red Galactic nova V838 Monocerotis.[12] Analysis of historical images of the area of the OT suggest with 70% certainty that the progenitor formed in a burst of stars around 8–13 Myr ago and implies the progenitor's mass to be 12–25 M assuming the OT is due to an evolving massive star.[13]

NGC 300 zoom-in by the Hubble Space Telescope
NGC 300 by GALEX, in ultraviolet light

However, in 2008 a bright mid-infrared progenitor to the transient was discovered in historical Spitzer data. This was a star that was obscured by dust, with energy distribution analogous to a black-body of R ≈ 300 AU and radiating at T ≈ 300 K with Lbol×106 L. This demonstrated that the transient was associated with an energetic explosion of a low-mass ≈ 10 M star. The transient's low luminosity as compared to typical core-collapse supernova, combined with its spectral attributes and dust covered properties, make it nearly identical to NGG 6946's SN 2008S.[12]

The spectrum of NGC 300-OT observed with Spitzer shows strong, broad emission features at 8 μm and 12 μm. Such features are also seen in Galactic carbon-rich protoplanetary nebulae.[12]

SN 2010da

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On May 23, 2010, Monard discovered another transient object of 16th magnitude, denoted as SN 2010da.[15] The optical transient was detected 15".9 west and 16".8 north the center of the galaxy at coordinates 00 55 04.86 −37 41 43.7.[16]

Two sets of independent follow-up spectroscopy data suggested that this was again another optical transient rather than a supernova, possibly an outbursting luminous blue variable star according to one spectrum,[17][18] as earlier predicted from the nature of the candidate mid-infrared progenitor.[19] The transient faded by 0.5–0.7 mag in 9 days, much faster than the 2008 transient in NGC 300.[20]

Other Novae and Supernovae

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AT 2019qyl was discovered on 26 September 2019, at magnitude 17.1. It was initially classified as a type IIn/LBV,[21] but later analysis classified the star as a classical nova.[22]

SN 2020acli (type IIn-pec, mag. 18.4) was discovered on 12 December 2020.[23]

Binary black hole system

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An x-ray source in NGC 300 is designated NGC 300 X-1.[24] Astronomers speculate that NGC 300 X-1 is a new kind of Wolf-Rayet + stellar black hole binary system similar to the confirmed such system IC 10 X-1.[24] Their shared properties include an orbital period of 32.8 hours. The black hole has a mass of 17 ± 4 M and the WR star has a mass of 26+7
−5
M. Both objects orbit each other at a distance of about 18.2 R.[25]

WO star

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There is an oxygen-sequence Wolf-Rayet star (WO4 type), known as STWR 13, located in one of the bright H II regions in NGC 300.[26]

Notes

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  1. ^ Average (1.845±0.125, 1.86±0.07) = ((1.845 + 1.86) / 2) ± ((0.1252 + 0.072)0.5 / 2) = 1.86 ± 0.07

See also

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References

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  1. ^ a b c d e f g h "NASA/IPAC Extragalactic Database". Results for NGC 300. Retrieved 2006-11-18.
  2. ^ a b c d e Rizzi, L.; Bresolin, F.; Kudritzki, R.-P.; Gieren, W.; et al. (2006). "The Araucaria Project: The Distance to NGC 300 from the Red Giant Branch Tip Using HST ACS Imaging". The Astrophysical Journal. 638 (2): 766–771. arXiv:astro-ph/0510298. Bibcode:2006ApJ...638..766R. doi:10.1086/498705. S2CID 15632452.
  3. ^ a b Westmeier, T.; Braun, R.; Koribalski, B. S. (2011-02-01). "Gas and dark matter in the Sculptor group: NGC 300". Monthly Notices of the Royal Astronomical Society. 410 (4): 2217–2236. arXiv:1009.0317. Bibcode:2011MNRAS.410.2217W. doi:10.1111/j.1365-2966.2010.17596.x. S2CID 119264221.
  4. ^ Stoyan, Ronald; Schurig, Stephan (2014). interstellarum Deep Sky Atlas. Erlangen: Cambridge University Press; Oculum-Verlag GmbH. ISBN 978-1-107-50338-0. OCLC 920437579.
  5. ^ Seligman, Courtney. "New General Catalogue Objects: NGC 300". Celestial Atlas. Retrieved 30 August 2024.
  6. ^ Vlajić, M.; Bland-hawthorn, J.; Freeman, K.C. (2009). "The Abundance Gradient in the Extremely Faint Outer Disk of NGC 300". The Astrophysical Journal. 697 (1): 361–372. arXiv:0903.1855. Bibcode:2009ApJ...697..361V. doi:10.1088/0004-637X/697/1/361. S2CID 15805386.
  7. ^ "NGC 300, a spiral galaxy in Sculptor". 8 July 2014.
  8. ^ Karachentsev, I.D.; Grebel, E.K.; Sharina, M.E.; Dolphin, A.E.; et al. (2003). "Distances to nearby galaxies in Sculptor". Astronomy and Astrophysics. 404: 93–111. arXiv:astro-ph/0302045. Bibcode:2003A&A...404...93K. doi:10.1051/0004-6361:20030170. S2CID 54977869.
  9. ^ van de Steene, G.C.; Jacoby, G.H.; Praet, C.; Ciardullo, R.; Dejonghe, H. (2006). "Distance determination to NGC 55 from the planetary nebula luminosity function". Astronomy and Astrophysics. 455 (3): 891–896. Bibcode:2006A&A...455..891V. doi:10.1051/0004-6361:20053475.
  10. ^ Sandage, A. (1986). "The redshift-distance relation. IX - Perturbation of the very nearby velocity field by the mass of the Local Group". Astrophysical Journal. 307: 1–19. Bibcode:1986ApJ...307....1S. doi:10.1086/164387.
  11. ^ 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. S2CID 120973010.
  12. ^ a b c d e f g Prieto, J.L.; Sellgren, K.; Thompson, T.A.; Kochanek, C.S. (2009). "A Spitzer/IRS Spectrum of the 2008 Luminous Transient in NGC 300: Connection to Proto-Planetary Nebulae". The Astrophysical Journal. 705 (2): 1425–1432. arXiv:0907.0230. Bibcode:2009ApJ...705.1425P. doi:10.1088/0004-637X/705/2/1425. S2CID 15627891.
  13. ^ a b Gogarten, S.M.; Dalcanton, J.J.; Murphy, J.W.; Williams, B.F.; et al. (2009). "The NGC 300 Transient: An Alternative Method for Measuring Progenitor Masses". The Astrophysical Journal. 703 (1): 300–310. arXiv:0907.0710. Bibcode:2009ApJ...703..300G. doi:10.1088/0004-637X/703/1/300. S2CID 8131611.
  14. ^ a b c d e f g h Bond, H.E.; Bedin, L.R.; Bonanos, A.Z.; Humphreys, R.M.; et al. (2009). "The 2008 Luminous Optical Transient in the Nearby Galaxy NGC 300". The Astrophysical Journal Letters. 695 (2): L154–L158. arXiv:0901.0198. Bibcode:2009ApJ...695L.154B. doi:10.1088/0004-637X/695/2/L154. S2CID 15953172.
  15. ^ "ATEL 2640: Optical Photometry of the New Optical Transient SN 2010da in NGC 300". Astronomers Telegram. 2010-05-26. Retrieved 2010-05-25.
  16. ^ "List of Supernovae". Central Bureau for Astronomical Telegrams. Retrieved 2011-07-03.
  17. ^ "ATEL 2636: SN 2010da is a SN impostor". Astronomers Telegram. 2010-05-25. Retrieved 2010-05-25.
  18. ^ "ATEL 2637: Spectroscopy of SN 2010da in NGC 300". Astronomers Telegram. 2010-05-25. Retrieved 2010-05-25.
  19. ^ "ATEL 2632: Mid-IR progenitor of SN 2010da in NGC 300". Astronomers Telegram. 2010-05-24. Retrieved 2010-05-25.
  20. ^ "ATEL 2660: Optical and Near-IR Follow-up of SN 2010da: Evidence for Warm Dust". Astronomers Telegram. 2010-06-04. Retrieved 2010-06-11.
  21. ^ "Classification certificate for object 2019qyl". Transient Name Server. IAU. Retrieved 17 August 2024.
  22. ^ "AT 2019qyl". Transient Name Server. IAU. Retrieved 16 August 2024.
  23. ^ Transient Name Server entry for SN 2020acli. Retrieved 25 March 2023.
  24. ^ a b Barnard, R.; Clark, J.S.; Kolb, U.C. (2008). "NGC 300 X-1 and IC 10 X-1: a new breed of black hole binary?". Astronomy and Astrophysics. 488 (2): 697–703. arXiv:0807.0606. Bibcode:2008A&A...488..697B. doi:10.1051/0004-6361:20077975. S2CID 1234999.
  25. ^ Binder, Breanna A.; Sy, Janelle M.; Eracleous, Michael; Christodoulou, Dimitris M.; Bhattacharya, Sayantan; Cappallo, Rigel; Laycock, Silas; Plucinsky, Paul P.; Williams, Benjamin F. (2021-03-01). "The Wolf-Rayet + Black Hole Binary NGC 300 X-1: What is the Mass of the Black Hole?". The Astrophysical Journal. 910 (1): 74. arXiv:2102.07065. Bibcode:2021ApJ...910...74B. doi:10.3847/1538-4357/abe6a9. ISSN 0004-637X.
  26. ^ Breysacher, J.; Azzopardi, M.; Testor, G.; Muratorio, G. (1997-10-01). "Wolf-Rayet stars detected in five associations of NGC 300". Astronomy and Astrophysics. 326: 976–981. Bibcode:1997A&A...326..976B. ISSN 0004-6361.
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