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Andromedids

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Andromedids
Diagram showing star positions and boundaries of the Ursa Minor constellation and its surroundings
Radiant of the Andromedids in December 2013 near γ Cassiopeiae (near the middle of the W)[1]
Parent body3D/Biela
Radiant
ConstellationAndromeda
Right ascension01h 36m [2]
Declination+37°[2]
Properties
Occurs duringSeptember 25 – December 6[3]
Date of peakNovember 9[2]
Velocity19[2] km/s
Zenithal hourly rate3[2]
See also: List of meteor showers

The Andromedids meteor shower is associated with Biela's Comet, the showers occurring as Earth passes through old streams left by the comet's tail. The comet was observed to have broken up by 1846; further drift of the pieces by 1852 suggested the moment of breakup was in either 1842 or early 1843, when the comet was near Jupiter.[4][5] The breakup led to particularly spectacular showers in subsequent cycles (particularly in 1872 and 1885).[3][6]

In the early 19th century, before the break-up of comet 3D/Biela, the radiant was in Cassiopeia.[7] In the last century the radiant of the modern weaker meteor shower is generally in the constellation of Andromeda as the name of the shower suggests, but due to its age and diffuseness meteors may appear to come from the neighbouring constellations, such as Pisces, Triangulum and Cassiopeia.[2][4]

Historical appearances

The Andromedids of 27 November 1872, a product of the breakup of Biela's Comet several decades previously.

The first known sighting of the Andromedids was December 6, 1741, over St Petersburg, Russia.[6] Further strong showers were witnessed in 1798, 1825, 1830, 1838 and 1847. The Andromedids produced spectacular displays of several thousand meteors per hour in 1872 and 1885, as a result of Earth crossing the comet's debris stream. Schmidt, observing from Athens, said that the 1872 shower consisted mainly of faint (5th to 6th magnitude) meteors with "broad and smoke-like" trains and a predominantly orange or reddish colouration.[8] In England, Lowe estimated the same shower as producing at least 58,600 visible meteors between 5.50 and 10.30 pm, observed that the meteors were much slower than the Leonids, and noted noises "like very distant gun-shots" several times to the north-west.[9] In Burma, the 1885 shower was perceived as a fateful omen and was indeed followed swiftly by the collapse of the Konbaung dynasty and the conquest by Britain.[10]

The November 27, 1885, shower was the occasion of the first known photograph of a meteor, taken by Austro-Hungarian astronomer, Ladislaus Weinek, who caught a 7mm-long trail on a plate at his Prague observing station.[11]

Current activity

Since the 19th century the Andromedids have faded so substantially that they are no longer generally visible to the naked eye, though some activity is still observable each year in mid-November given suitable detection equipment.[6] In recent years, peak activity had been less than three meteors per hour, around November 9[2] to 14.[3] Andromedid activity of November comes from the newest streams, while that of early December comes from the oldest.[3]

On December 4, 2011, six Canadian radar stations detected 50 meteors in an hour. The activity was likely from the 1649 stream.[7] On December 8, 2013, Meteor specialist Peter Brown reported that the Canadian Meteor Orbit Radar had recorded an outburst from the Andromedid meteors in the past 24 hours.[1] Scientists postulated a somewhat weaker return in 2018, but a yield of up to 200 meteors an hour in 2023.[7][12] [needs update] Canadian Meteor Orbit Radar (CMOR) data also detected a spike of 30 meteors per hour on November 27, 2008.[7]

During the 2012 shower an inconspicuous maximum occurred on November 9.[2]

References

  1. ^ a b Kelly Beatty (8 December 2013). "An Outburst of Andromedid Meteors". Sky & Telescope. Retrieved 2013-12-09.
  2. ^ a b c d e f g h "Meteor Activity Outlook for November 17-23, 2012". International Meteor Organization (IMO). Archived from the original on 2013-06-22. Retrieved 2012-12-11.
  3. ^ a b c d Gary W. Kronk. "Observing the Andromedids". Meteor Showers Online. Archived from the original on 2013-01-22. Retrieved 2011-04-18.
  4. ^ a b Peter Jenniskens (3 April 2008). "The Mother of All Meteor Storms". Space.com. Retrieved 2011-04-18.
  5. ^ Jenniskens, Peter; Vaubaillon, J. R. M. (2007). "3D/Biela and the Andromedids: Fragmenting versus Sublimating Comets" (PDF). Astronomical Journal. 134 (3): 1037–1045. Bibcode:2007AJ....134.1037J. doi:10.1086/519074. S2CID 18785028.
  6. ^ a b c Carl W. Hergenrother (15 November 2008). "The Meteor Storms of November – Part I – The Andromedids". The Transient Sky Blog. Retrieved 2011-04-18.
  7. ^ a b c d Paul A. Wiegert; Peter G. Brown; Robert J. Weryk; Daniel K. Wong (26 Sep 2012). "The return of the Andromedids meteor shower". Astronomical Journal. 145 (3): 70. arXiv:1209.5980. Bibcode:2013AJ....145...70W. doi:10.1088/0004-6256/145/3/70. S2CID 118626625.
  8. ^ "Meteors of Nov. 27th, 1872, in Europe". American Journal of Science. 5 (26): 153. Feb 1873. Retrieved 21 May 2022.
  9. ^ "Meteors of Nov. 27th, 1872, in Europe". American Journal of Science. 5 (26): 152. Feb 1873. Retrieved 21 May 2022.
  10. ^ Lonely Planet Myanmar, 10th edition page 256
  11. ^ Hughes, Stefan (2012). Catchers of the Light: The Astrophotographers' Family History. S. Hughes. p. 457. ISBN 978-1620509616.
  12. ^ Croswell, Ken. "The Return of a Great 19th-Century Meteor Shower". Scientific American. Retrieved 19 October 2012.