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Precovery

April 09, 2024

In astronomy, precovery (short for pre-discovery recovery)[1][2] is the process of finding the image of an object in images or photographic plates predating its discovery, typically for the purpose of calculating a more accurate orbit. This happens most often with minor planets, but sometimes a comet, a dwarf planet, a natural satellite, or a star is found in old archived images; even exoplanet precovery observations have been obtained.[3] "Precovery" refers to a pre-discovery image; "recovery" refers to imaging of a body which was lost to our view (as behind the Sun), but is now visible again (also see lost minor planet and lost comet).

The Jupiter moon Valetudo was first discovered in 2017, but a number of precovery images have been identified since, including this one taken on 28 February 2003 by the Canada–France–Hawaii Telescope, in which Valetudo's position is marked by the two orange bars.

Orbit determination requires measuring an object's position on multiple occasions. The longer the interval between observations, the more accurately the orbit can be calculated; however, for a newly discovered object, only a few days' or weeks' worth of measured positions may be available, sufficient only for a preliminary (imprecise) orbit calculation.

When an object is of particular interest (such as asteroids with a chance of impacting Earth), researchers begin a search for precovery images. Using the preliminary orbit calculation to predict where the object might appear on old archival images, those images (sometimes decades old) are searched to see if it had in fact already been photographed. If so, a far longer observation arc can allow a far more precise orbital calculation.

Until fast computers were widely available, it was impractical to analyze and measure images for possible minor planet discoveries because this required much human labor. Usually, such images were made years or decades earlier for other purposes (studies of galaxies, etc.), and it was not worth the time it took to look for precovery images of ordinary asteroids. Today, computers can easily analyze digital astronomical images and compare them to star catalogs containing up to a billion or so star positions to see if one of the "stars" is actually a precovery image of the newly discovered object. This technique has been used since the mid-1990s to determine the orbits of many minor planets.

Examples edit

In an extreme case of precovery, an object was discovered on December 31, 2000, designated 2000 YK66, and a near-Earth orbit was calculated. Precovery revealed that it had previously been discovered on February 23, 1950 and given the provisional designation 1950 DA, and then been lost for half a century. The exceptionally long observation period allowed an unusually precise orbit calculation, and the asteroid was determined to have a small chance of colliding with the Earth. After an asteroid's orbit is calculated with sufficient precision, it can be assigned a number prefix (in this case, (29075) 1950 DA).

The asteroid 69230 Hermes was found in 2003 and numbered, but was found to be a discovery from 1937 which had been named "Hermes", but subsequently lost; its old name was reinstated. Centaur 2060 Chiron was discovered in 1977, and precovery images from 1895 have been located.[4]

Another noteworthy case of precovery concerns Neptune. Galileo observed Neptune on both December 28, 1612 and January 27, 1613, when it was in a portion of its orbit where it was nearly directly behind Jupiter as seen from Earth. Because Neptune moves very slowly and is very faint relative to the known planets of that time, Galileo mistook it for a fixed star, leaving the planet undiscovered until 1846. He did note that the "star" Neptune did seem to move, noting that between his two observations its apparent distance from another star had changed. However, unlike photographic images, drawings such as those Galileo made are usually not precise enough to be of use in refining an object's orbit. In 1795, Lalande also mistook Neptune for a star.[5] In 1690, John Flamsteed did the same with Uranus, even cataloging it as "34 Tauri".

One of the most exceptional suggested instances is related to the discovery of Ganymede. This again involved Galileo, who is usually stated to have discovered it in 1610. It has been postulated by Xi Zezong that Ganymede was discovered by the Chinese astronomer Gan De in 365 B.C., when he catalogued it as a small red star next to Jupiter during naked eye observation.[6]

Dwarf planets edit

Discovery and precovery dates for well-known dwarf planets, minor planets and probable dwarf planets:

Index Object Discovery
Year		 Precovery
Year 		Years Elapsed Absolute
Magnitude
2 Pallas 1802 1779[7] 23 4.13
134340 Pluto 1930 1909[8] 21 -0.7
19521 Chaos 1998 1991 [9] 7 5.0
20000 Varuna 2000 1954[10] 46 3.76
38628 Huya 2000 1996[11] 4 5.04
78799 2002 XW93 2002 1989 [12] 13 5.5
28978 Ixion 2001 1982[13] 19 3.6
55637 2002 UX25 2002 1991 [14] 11 3.87
50000 Quaoar 2002 1954[15] 48 2.82
307261 2002 MS4 2002 1954[16] 48 3.7
55565 2002 AW197 2002 1997 [17] 5 3.5
2002 XV93 2002 1990 [18] 12 5.42
174567 Varda 2003 1980 [19] 23 3.1
84922 2003 VS2 2003 1991 [20] 12 4.1
208996 2003 AZ84 2003 1996 [21] 7 3.54
455502 2003 UZ413 2003 1954 [22] 49 4.38
90377 Sedna 2003 1990[23] 13 1.83
444030 2004 NT33 2004 1982 [24] 22 4.4
230965 2004 XA192 2004 1989 [25] 15 4.1
90568 2004 GV9 2004 1954 [26] 50 4.25
90482 Orcus 2004 1951[27] 53 2.2
175113 2004 PF115 2004 1992 [28] 12 4.54
120347 Salacia 2004 1982 [29] 22 4.36
120348 2004 TY364 2004 1983 [30] 21 4.52
136108 Haumea 2004 1955[31] 49 0.2
145451 2005 RM43 2005 1976 [32] 29 4.4
145452 2005 RN43 2005 1954 [33] 51 3.89
202421 2005 UQ513 2005 1990 [34] 15 3.4
136199 Eris 2005 1954[35] 51 -1.17
136472 Makemake 2005 1955[36] 50 -0.3
470308 2007 JH43 2007 1984 [37] 23 4.49
229762 Gǃkúnǁʼhòmdímà 2007 1982 [38] 25 3.69
225088 Gonggong 2007 1985[39] 22 1.8
523671 2013 FZ27 2013 2001[40] 12 4.1
472271 2014 UM33 2014 2003 [41] 11 5.2
523794 2015 RR245 2015 2004[42] 11 3.6
2018 VG18 2018 2003 [43] 15 3.5

Oort cloud comets edit

Oort cloud comets can take 10+ years going from Neptune's orbit at 30.1 AU (4.50 billion km) to perihelion (closest approach to the Sun). As modern survey archives reach fainter magnitudes and are more comprehensive, significant precovery images have become easier to locate.

Oort Cloud Comets
Comet Discovery
date 		Precovery
date 		Discovery
distance
from Sun (AU) 		Precovery
distance
from Sun (AU) 		Ref
C/2010 U3 (Boattini) 2010-10-31 2005-11-05 18.4 25.8 JPL
C/2012 S1 (ISON) 2012-09-21 2011-09-30 6.3 9.4 JPL
C/2013 A1 (Siding Spring) 2013-01-03 2012-10-04 7.2 7.9 JPL
C/2017 K2 (PANSTARRS) 2017-05-21 2013-05-12 16.1 23.7 JPL

See also edit

References edit

  1. ^ McNaught, R. H.; Steel, D. I.; Russell, K. S.; Williams, G. V. (March 7–11, 1994). "Near-Earth Asteroids on Archival Schmidt Plates". In Jessica Chapman; Russell Cannon; Sandra Harrison; Bambang Hidayat (eds.). Proceedings, The future utilisation of Schmidt telescopes. IAU Colloquium 148. Vol. 84. Bandung, Indonesia: Astronomical Society of the Pacific. p. 170. Bibcode:1995ASPC...84..170M.
  2. ^ D.I. Steel, R.H. McNaught, G.J. Garradd, D.J. Asher and K.S. Russell (25 March 1997). . Archived from the original on 2012-07-28.{{cite web}}: CS1 maint: multiple names: authors list (link)
  3. ^ Villard, Ray; Lafreniere, David (April 1, 2009). "Hubble Finds Hidden Exoplanet in Archival Data". HubbleSite NewsCenter. NASA. from the original on April 5, 2009. Retrieved 2009-04-03.
  4. ^ "JPL Small-Body Database Browser: 2060 Chiron (1977 UB)" (2009-09-17 last obs). from the original on 2011-06-09. Retrieved 2010-02-08.
  5. ^ Fred William Price (2000). The planet observer's handbook. Cambridge University Press. p. 352. ISBN 9780521789813. Retrieved 2009-09-11.
  6. ^ . Archived from the original on 2017-12-01. Retrieved 27 November 2017.
  7. ^ "Charles Messier, premier observateur de l'astéroïde Pallas". cieletespace.fr. from the original on 16 March 2016. Retrieved 7 May 2018.
  8. ^ Wild, W. J.; Buchwald, G.; Dimario, M. J.; Standish, E. M. (December 1998). "Serendipitous Discovery of the Oldest Known Photographic Plates with Images of Pluto". American Astronomical Society. 30: 1449. Bibcode:1998DPS....30.5514W.
  9. ^ "JPL Small-Body Database Browser".
  10. ^ Chamberlin, Alan. "JPL Small-Body Database Browser". ssd.jpl.nasa.gov. from the original on 7 May 2018. Retrieved 7 May 2018.
  11. ^ "JPL Small-Body Database Browser: 38628 Huya (2000 EB173)" (2009-06-13 last obs). from the original on 2018-05-07. Retrieved 2010-02-09.
  12. ^ "JPL Small-Body Database Browser".
  13. ^ "JPL Small-Body Database Browser: 28978 Ixion (2001 KX76)" (2009-05-21 last obs). from the original on 2015-11-05. Retrieved 2010-02-08.
  14. ^ "JPL Small-Body Database Browser".
  15. ^ "JPL Small-Body Database Browser: 50000 Quaoar (2002 LM60)" (2009-09-12 last obs). from the original on 2011-06-11. Retrieved 2010-02-08.
  16. ^ "JPL Small-Body Database Browser: (2002 MS4)". 2011-12-12. from the original on 2012-04-15. Retrieved 2015-01-28.
  17. ^ "JPL Small-Body Database Browser".
  18. ^ "JPL Small-Body Database Browser".
  19. ^ "JPL Small-Body Database Browser".
  20. ^ "JPL Small-Body Database Browser".
  21. ^ "JPL Small-Body Database Browser".
  22. ^ "JPL Small-Body Database Browser".
  23. ^ "JPL Small-Body Database Browser: 90377 Sedna (2003 VB12)" (2010-01-05 last obs). Archived from the original on 2016-03-25. Retrieved 2010-02-08.
  24. ^ "JPL Small-Body Database Browser".
  25. ^ "JPL Small-Body Database Browser".
  26. ^ "JPL Small-Body Database Browser".
  27. ^ "JPL Small-Body Database Browser: 90482 Orcus (2004 DW)" (2009-04-28 last obs). from the original on 2015-11-05. Retrieved 2010-02-08.
  28. ^ "JPL Small-Body Database Browser".
  29. ^ "JPL Small-Body Database Browser".
  30. ^ "JPL Small-Body Database Browser".
  31. ^ "JPL Small-Body Database Browser: 136108 Haumea (2003 EL61)" (2010-01-26 last obs). from the original on 2011-06-09. Retrieved 2010-02-08.
  32. ^ "JPL Small-Body Database Browser".
  33. ^ "JPL Small-Body Database Browser".
  34. ^ "JPL Small-Body Database Browser".
  35. ^ "JPL Small-Body Database Browser: 136199 Eris (2003 UB313)" (2009-11-20 last obs). from the original on 2011-05-12. Retrieved 2010-02-08.
  36. ^ "JPL Small-Body Database Browser: 136472 Makemake (2005 FY9)" (2010-01-26 last obs). from the original on 2011-08-30. Retrieved 2010-02-08.
  37. ^ "JPL Small-Body Database Browser".
  38. ^ "JPL Small-Body Database Browser".
  39. ^ "JPL Small-Body Database Browser: 225088 (2007 OR10)" (2009-10-19 last obs). from the original on 2011-11-15. Retrieved 2010-02-08.
  40. ^ "JPL Small-Body Database Browser: 2013 FZ27)" (2014-03-26 last obs). Retrieved 2015-04-13.
  41. ^ "JPL Small-Body Database Browser".
  42. ^ "JPL Small-Body Database Browser: 2015 RR245)" (2016-06-08 last obs). from the original on 2016-12-27. Retrieved 2016-12-26.
  43. ^ "JPL Small-Body Database Browser".

External links edit

 
Look up precovery in Wiktionary, the free dictionary.
  • SkyMorph GSFC

April 09, 2024
precovery, astronomy, precovery, short, discovery, recovery, process, finding, image, object, images, photographic, plates, predating, discovery, typically, purpose, calculating, more, accurate, orbit, this, happens, most, often, with, minor, planets, sometime. In astronomy precovery short for pre discovery recovery 1 2 is the process of finding the image of an object in images or photographic plates predating its discovery typically for the purpose of calculating a more accurate orbit This happens most often with minor planets but sometimes a comet a dwarf planet a natural satellite or a star is found in old archived images even exoplanet precovery observations have been obtained 3 Precovery refers to a pre discovery image recovery refers to imaging of a body which was lost to our view as behind the Sun but is now visible again also see lost minor planet and lost comet The Jupiter moon Valetudo was first discovered in 2017 but a number of precovery images have been identified since including this one taken on 28 February 2003 by the Canada France Hawaii Telescope in which Valetudo s position is marked by the two orange bars Orbit determination requires measuring an object s position on multiple occasions The longer the interval between observations the more accurately the orbit can be calculated however for a newly discovered object only a few days or weeks worth of measured positions may be available sufficient only for a preliminary imprecise orbit calculation When an object is of particular interest such as asteroids with a chance of impacting Earth researchers begin a search for precovery images Using the preliminary orbit calculation to predict where the object might appear on old archival images those images sometimes decades old are searched to see if it had in fact already been photographed If so a far longer observation arc can allow a far more precise orbital calculation Until fast computers were widely available it was impractical to analyze and measure images for possible minor planet discoveries because this required much human labor Usually such images were made years or decades earlier for other purposes studies of galaxies etc and it was not worth the time it took to look for precovery images of ordinary asteroids Today computers can easily analyze digital astronomical images and compare them to star catalogs containing up to a billion or so star positions to see if one of the stars is actually a precovery image of the newly discovered object This technique has been used since the mid 1990s to determine the orbits of many minor planets Contents 1 Examples 1 1 Dwarf planets 1 2 Oort cloud comets 2 See also 3 References 4 External linksExamples editIn an extreme case of precovery an object was discovered on December 31 2000 designated 2000 YK66 and a near Earth orbit was calculated Precovery revealed that it had previously been discovered on February 23 1950 and given the provisional designation 1950 DA and then been lost for half a century The exceptionally long observation period allowed an unusually precise orbit calculation and the asteroid was determined to have a small chance of colliding with the Earth After an asteroid s orbit is calculated with sufficient precision it can be assigned a number prefix in this case 29075 1950 DA The asteroid 69230 Hermes was found in 2003 and numbered but was found to be a discovery from 1937 which had been named Hermes but subsequently lost its old name was reinstated Centaur 2060 Chiron was discovered in 1977 and precovery images from 1895 have been located 4 Another noteworthy case of precovery concerns Neptune Galileo observed Neptune on both December 28 1612 and January 27 1613 when it was in a portion of its orbit where it was nearly directly behind Jupiter as seen from Earth Because Neptune moves very slowly and is very faint relative to the known planets of that time Galileo mistook it for a fixed star leaving the planet undiscovered until 1846 He did note that the star Neptune did seem to move noting that between his two observations its apparent distance from another star had changed However unlike photographic images drawings such as those Galileo made are usually not precise enough to be of use in refining an object s orbit In 1795 Lalande also mistook Neptune for a star 5 In 1690 John Flamsteed did the same with Uranus even cataloging it as 34 Tauri One of the most exceptional suggested instances is related to the discovery of Ganymede This again involved Galileo who is usually stated to have discovered it in 1610 It has been postulated by Xi Zezong that Ganymede was discovered by the Chinese astronomer Gan De in 365 B C when he catalogued it as a small red star next to Jupiter during naked eye observation 6 Dwarf planets edit Discovery and precovery dates for well known dwarf planets minor planets and probable dwarf planets Index Object DiscoveryYear PrecoveryYear Years Elapsed AbsoluteMagnitude2 Pallas 1802 1779 7 23 4 13134340 Pluto 1930 1909 8 21 0 719521 Chaos 1998 1991 9 7 5 020000 Varuna 2000 1954 10 46 3 7638628 Huya 2000 1996 11 4 5 0478799 2002 XW93 2002 1989 12 13 5 528978 Ixion 2001 1982 13 19 3 655637 2002 UX25 2002 1991 14 11 3 8750000 Quaoar 2002 1954 15 48 2 82307261 2002 MS4 2002 1954 16 48 3 755565 2002 AW197 2002 1997 17 5 3 52002 XV93 2002 1990 18 12 5 42174567 Varda 2003 1980 19 23 3 184922 2003 VS2 2003 1991 20 12 4 1208996 2003 AZ84 2003 1996 21 7 3 54455502 2003 UZ413 2003 1954 22 49 4 3890377 Sedna 2003 1990 23 13 1 83444030 2004 NT33 2004 1982 24 22 4 4230965 2004 XA192 2004 1989 25 15 4 190568 2004 GV9 2004 1954 26 50 4 2590482 Orcus 2004 1951 27 53 2 2175113 2004 PF115 2004 1992 28 12 4 54120347 Salacia 2004 1982 29 22 4 36120348 2004 TY364 2004 1983 30 21 4 52136108 Haumea 2004 1955 31 49 0 2145451 2005 RM43 2005 1976 32 29 4 4145452 2005 RN43 2005 1954 33 51 3 89202421 2005 UQ513 2005 1990 34 15 3 4136199 Eris 2005 1954 35 51 1 17136472 Makemake 2005 1955 36 50 0 3470308 2007 JH43 2007 1984 37 23 4 49229762 Gǃkunǁʼhomdima 2007 1982 38 25 3 69225088 Gonggong 2007 1985 39 22 1 8523671 2013 FZ27 2013 2001 40 12 4 1472271 2014 UM33 2014 2003 41 11 5 2523794 2015 RR245 2015 2004 42 11 3 62018 VG18 2018 2003 43 15 3 5Oort cloud comets edit Oort cloud comets can take 10 years going from Neptune s orbit at 30 1 AU 4 50 billion km to perihelion closest approach to the Sun As modern survey archives reach fainter magnitudes and are more comprehensive significant precovery images have become easier to locate Oort Cloud Comets Comet Discoverydate Precoverydate Discoverydistancefrom Sun AU Precoverydistancefrom Sun AU RefC 2010 U3 Boattini 2010 10 31 2005 11 05 18 4 25 8 JPLC 2012 S1 ISON 2012 09 21 2011 09 30 6 3 9 4 JPLC 2013 A1 Siding Spring 2013 01 03 2012 10 04 7 2 7 9 JPLC 2017 K2 PANSTARRS 2017 05 21 2013 05 12 16 1 23 7 JPLSee also editDiscovery image DANEOPSReferences edit McNaught R H Steel D I Russell K S Williams G V March 7 11 1994 Near Earth Asteroids on Archival Schmidt Plates In Jessica Chapman Russell Cannon Sandra Harrison Bambang Hidayat eds Proceedings The future utilisation of Schmidt telescopes IAU Colloquium 148 Vol 84 Bandung Indonesia Astronomical Society of the Pacific p 170 Bibcode 1995ASPC 84 170M D I Steel R H McNaught G J Garradd D J Asher and K S Russell 25 March 1997 AANEAS A Valedictory Report Archived from the original on 2012 07 28 a href Template Cite web html title Template Cite web cite web a CS1 maint multiple names authors list link Villard Ray Lafreniere David April 1 2009 Hubble Finds Hidden Exoplanet in Archival Data HubbleSite NewsCenter NASA Archived from the original on April 5 2009 Retrieved 2009 04 03 JPL Small Body Database Browser 2060 Chiron 1977 UB 2009 09 17 last obs Archived from the original on 2011 06 09 Retrieved 2010 02 08 Fred William Price 2000 The planet observer s handbook Cambridge University Press p 352 ISBN 9780521789813 Retrieved 2009 09 11 Galilean Moons Gan De Archived from the original on 2017 12 01 Retrieved 27 November 2017 Charles Messier premier observateur de l asteroide Pallas cieletespace fr Archived from the original on 16 March 2016 Retrieved 7 May 2018 Wild W J Buchwald G Dimario M J Standish E M December 1998 Serendipitous Discovery of the Oldest Known Photographic Plates with Images of Pluto American Astronomical Society 30 1449 Bibcode 1998DPS 30 5514W JPL Small Body Database Browser Chamberlin Alan JPL Small Body Database Browser ssd jpl nasa gov Archived from the original on 7 May 2018 Retrieved 7 May 2018 JPL Small Body Database Browser 38628 Huya 2000 EB173 2009 06 13 last obs Archived from the original on 2018 05 07 Retrieved 2010 02 09 JPL Small Body Database Browser JPL Small Body Database Browser 28978 Ixion 2001 KX76 2009 05 21 last obs Archived from the original on 2015 11 05 Retrieved 2010 02 08 JPL Small Body Database Browser JPL Small Body Database Browser 50000 Quaoar 2002 LM60 2009 09 12 last obs Archived from the original on 2011 06 11 Retrieved 2010 02 08 JPL Small Body Database Browser 2002 MS4 2011 12 12 Archived from the original on 2012 04 15 Retrieved 2015 01 28 JPL Small Body Database Browser JPL Small Body Database Browser JPL Small Body Database Browser JPL Small Body Database Browser JPL Small Body Database Browser JPL Small Body Database Browser JPL Small Body Database Browser 90377 Sedna 2003 VB12 2010 01 05 last obs Archived from the original on 2016 03 25 Retrieved 2010 02 08 JPL Small Body Database Browser JPL Small Body Database Browser JPL Small Body Database Browser JPL Small Body Database Browser 90482 Orcus 2004 DW 2009 04 28 last obs Archived from the original on 2015 11 05 Retrieved 2010 02 08 JPL Small Body Database Browser JPL Small Body Database Browser JPL Small Body Database Browser JPL Small Body Database Browser 136108 Haumea 2003 EL61 2010 01 26 last obs Archived from the original on 2011 06 09 Retrieved 2010 02 08 JPL Small Body Database Browser JPL Small Body Database Browser JPL Small Body Database Browser JPL Small Body Database Browser 136199 Eris 2003 UB313 2009 11 20 last obs Archived from the original on 2011 05 12 Retrieved 2010 02 08 JPL Small Body Database Browser 136472 Makemake 2005 FY9 2010 01 26 last obs Archived from the original on 2011 08 30 Retrieved 2010 02 08 JPL Small Body Database Browser JPL Small Body Database Browser JPL Small Body Database Browser 225088 2007 OR10 2009 10 19 last obs Archived from the original on 2011 11 15 Retrieved 2010 02 08 JPL Small Body Database Browser 2013 FZ27 2014 03 26 last obs Retrieved 2015 04 13 JPL Small Body Database Browser JPL Small Body Database Browser 2015 RR245 2016 06 08 last obs Archived from the original on 2016 12 27 Retrieved 2016 12 26 JPL Small Body Database Browser External links edit nbsp Look up precovery in Wiktionary the free dictionary SkyMorph GSFC Retrieved from https en wikipedia org w index php title Precovery amp oldid 1210323337, wikipedia, wiki, book, books, library,

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