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Meteoric iron

February 15, 2024

Meteoric iron, sometimes meteoritic iron,[1] is a native metal and early-universe protoplanetary-disk remnant found in meteorites and made from the elements iron and nickel, mainly in the form of the mineral phases kamacite and taenite. Meteoric iron makes up the bulk of iron meteorites but is also found in other meteorites. Apart from minor amounts of telluric iron, meteoric iron is the only naturally occurring native metal of the element iron (in metallic form rather than in an ore) on the Earth's surface.[2]

Meteoric iron (native iron)
Widmanstätten pattern on a 500g endcut from the Toluca iron meteorite
General
CategoryNative element mineral
Formula
(repeating unit)		Fe and Ni in different ratios
Space groupDifferent structures
Identification
LusterMetallic
DiaphaneityOpaque

Mineralogy edit

The bulk of meteoric iron consists of taenite and kamacite. Taenite is a face-centered cubic and kamacite a body-centered cubic iron-nickel alloy.

Meteoric iron can be distinguished from telluric iron by its microstructure and perhaps by its chemical composition also, since meteoritic iron contains more nickel and less carbon.[2]

Trace amounts of gallium and germanium in meteoric iron can be used to distinguish different meteorite types. The meteoric iron in stony iron meteorites is identical to the "gallium-germanium group" of the iron meteorites.[3]

Overview over meteoric iron mineral phases
Mineral Formula Nickel (Mass-% Ni) Crystal structure Notes & references
Antitaenite γLow Spin-(Ni,Fe) 20–40 face centered cubic Only approved as a variety of taenite by the IMA
Kamacite α-(Fe,Ni); Fe0+0.9Ni0.1 5–10 body centered cubic Same structure as ferrite
Taenite γ-(Ni,Fe) 20–65 face centered cubic Same structure as austenite
Tetrataenite (FeNi) 48–57 tetragonal [4]

Structures edit

Meteoric iron forms a few different structures that can be seen by etching or in thin sections of meteorites. The Widmanstätten pattern forms when meteoric iron cools and kamacite is exsolved from taenite in the form of lamellas.[5] Plessite is a more fine-grained intergrowth of the two minerals in between the lamella of the Widmanstätten pattern.[6] Neumann lines are fine lines running through kamacite crystals that form through impact-related deformation.[7]

Cultural and historical usage edit

 
A lance made from a narwhal tusk with an iron head made from the Cape York meteorite.

Before the advent of iron smelting, meteoric iron was the only source of iron metal apart from minor amounts of telluric iron. Meteoric iron was already used before the beginning of the Iron Age to make cultural objects, tools and weapons.[8]

Bronze Age edit

Iron in hieroglyphs

bjꜣ-n-p.t
literally "metal of the sky"

Many examples of iron working from the Bronze Age have been confirmed to be meteoritic in origin.[9]

  • In ancient Egypt an iron metal bead was found in a graveyard near Gerzeh that contained 7.5% Ni.[10][11] Dated to around 3200 BC, geochemical analysis of the Gerzeh iron beads, based on the ratio of nickel to iron and cobalt, confirms that the iron was meteoritic in origin.[9]
  • Dated to around 2500 BC, an iron dagger from Alaca Höyük was confirmed to be meteoritic in origin through geochemical analysis.[9]
  • Dated to around 2300 BC, an iron pendant from Umm el-Marra in Syria was confirmed to be meteoritic in origin through geochemical analysis.[9]
  • Dated to around 1400 BC, an iron axe from Ugarit in Syria was found to be meteoritic in origin.[9]
  • Dated to around 1400 BC, several iron axes from the Shang Dynasty in China were also confirmed to be meteoritic in origin.[9]
  • Dated to around 1350 BC, an iron dagger, bracelet and headrest from the tomb of Tutankhamun were confirmed to be meteoritic in origin.[9] The Tutankhamun dagger consists of similar proportions of metals (iron, nickel and cobalt) to a meteorite discovered in the area, deposited by an ancient meteor shower.[12][13][14]
  • Dated to around 900 BC, an iron arrowhead from Mörigen in Switzerland was confirmed to be meteoritic in origin.[15]

The Americas edit

Africa edit

  • Fragments from the Gibeon meteorite were used for centuries by the Nama people of Namibia.

Asia edit

  • There are reports of the use of meteorites for manufacture of various items in Tibet (see Thokcha).
  • The Iron Man, a purported Tibetan Buddhist statue of Vaiśravaṇa, was likely carved from an ataxite meteorite.[19] It has been speculated that it may be made from a fragment of the Chinga meteorite.[20][21]

Even after the invention of smelting, meteoric iron was sometimes used where this technology was not available or metal was scarce. A piece of the Cranbourne meteorite was made into a horseshoe around 1854.[22]

Today meteoritic iron is used in niche jewellery and knife production, but most of it is used for research, educational or collecting purposes.

Atmospheric phenomena edit

Meteoric iron also has an effect on the Earth's atmosphere. When meteorites descend through the atmosphere, outer parts are ablated. Meteoric ablation is the source of many elements in the upper atmosphere. When meteoric iron is ablated, it forms a free iron atom that can react with ozone (O3) to form FeO. This FeO may be the source of the orange spectrographic bands in the spectrum of the upper atmosphere.[23]

See also edit

References edit

  1. ^ Rehren, Thilo; Belgya, Tamás; Jambon, Albert; Káli, György; Kasztovszky, Zsolt; Kis, Zoltán; Kovács, Imre; Maróti, Boglárka; Martinón-Torres, Marcos; Miniaci, Gianluca; Pigott, Vincent C.; Radivojević, Miljana; Rosta, László; Szentmiklósi, László; Szőkefalvi-Nagy, Zoltán (2013). "5,000 years old Egyptian iron beads made from hammered meteoritic iron" (PDF). Journal of Archaeological Science. 40 (12): 4785–4792. doi:10.1016/j.jas.2013.06.002.
  2. ^ a b Fleming, Stuart J.; Schenck, Helen R. (1989). History of Technology: The Role of Metals. UPenn Museum of Archaeology. p. 67. ISBN 978-0-924171-95-6.
  3. ^ Lovering, John F.; Nichiporuk, Walter; Chodos, Arthur; Brown, Harrison (31 December 1956). "The distribution of gallium, germanium, cobalt, chromium, and copper in iron and stony-iron meteorites in relation to nickel content and structure". Geochimica et Cosmochimica Acta. 11 (4): 263–278. Bibcode:1957GeCoA..11..263L. doi:10.1016/0016-7037(57)90099-6.
  4. ^ Clarke, Roy S.; Edward R. D. Scott (1980). "Tetrataenite - ordered FeNi, a new mineral in meteorites" (PDF). American Mineralogist. 65: 624–630. Bibcode:1980AmMin..65..624C.
  5. ^ Yang, J.; J. I. Goldstein (2005). "The formation of the Widmanstätten structure in meteorites". Meteoritics & Planetary Science. 40 (2): 239–253. Bibcode:2005M&PS...40..239Y. doi:10.1111/j.1945-5100.2005.tb00378.x.
  6. ^ Goldstein, J. I.; J. R. Michael (2006). "The formation of plessite in meteoritic metal". Meteoritics & Planetary Science. 41 (4): 553–570. Bibcode:2006M&PS...41..553G. doi:10.1111/j.1945-5100.2006.tb00482.x.
  7. ^ Rosenhain, Walter; Jean McMinn (1925). "The Plastic Deformation of Iron and the Formation of Neumann Lines". Proceedings of the Royal Society. 108 (746): 231–239. Bibcode:1925RSPSA.108..231R. doi:10.1098/rspa.1925.0071.
  8. ^ Waldbaum, J. C. and James D. Muhly; The first archaeological appearance of iron and the transition to the iron age chapter in The coming of the age of iron, Theodore A. Wertme. ed., Yale University Press, 1980, ISBN 978-0300024258
  9. ^ a b c d e f g Jambon, Albert (2017). "Bronze Age iron: Meteoritic or not? A chemical strategy" (PDF). Journal of Archaeological Science. 88: 47–53. doi:10.1016/j.jas.2017.09.008. ISSN 0305-4403.
  10. ^ . ucl.ac.uk. Archived from the original on 7 April 2015. Retrieved 28 December 2012.
  11. ^ Rehren, Thilo; Belgya, Tamás; Jambon, Albert; Káli, György; et al. (31 July 2013). "5,000 years old Egyptian iron beads made from hammered meteoritic iron". Journal of Archaeological Science. 40 (12): 4785–4792. doi:10.1016/j.jas.2013.06.002. hdl:11568/908268.
  12. ^ Bjorkman, Judith Kingston (1973). "Meteors and Meteorites in the ancient Near East". Meteoritics. 8 (2): 91–132. Bibcode:1973Metic...8...91B. doi:10.1111/j.1945-5100.1973.tb00146.x.
  13. ^ Daniela Comelli; Massimo D'orazio; Luigi Folco; Mahmud El-Halwagy; Tommaso Frizzi; Roberto Alberti; Valentina Capogrosso; Abdelrazek Elnaggar; Hala Hassan; Austin Nevin; Franco Porcelli; Mohamed G. Rashed; Gianluca Valentini (2016). "The meteoritic origin of Tutankhamun's iron dagger blade". Meteoritics & Planetary Science. 51 (7): 1301–1309. Bibcode:2016M&PS...51.1301C. doi:10.1111/maps.12664.
  14. ^ Walsh, Declan (2 June 2016). "King Tut's Dagger Made of 'Iron From the Sky,' Researchers Say". The New York Times. Retrieved 4 June 2016. ...the blade's composition of iron, nickel and cobalt was an approximate match for a meteorite that landed in northern Egypt. The result "strongly suggests an extraterrestrial origin"
  15. ^ Guy, Jack (8 August 2023). "Arrowhead made from meteorite 3,000 years ago found near lake in Europe". CNN. Retrieved 9 August 2023.
  16. ^ Iron and steel in ancient times by Vagn Fabritius Buchwald - Det Kongelige Danske Videnskabernes Selskab 2005
  17. ^ T. A. Rickard (1941). "The Use of Meteoric Iron". Journal of the Royal Anthropological Institute. 71 (1/2): 55–66. doi:10.2307/2844401. JSTOR 2844401.
  18. ^ Buchwald, V. F. (1992). "On the Use of Iron by the Eskimos in Greenland". Materials Characterization. 29 (2): 139–176. doi:10.1016/1044-5803(92)90112-U. JSTOR 2844401.
  19. ^ Der Lama mit der Hose: „Buddha from space“ ist offenbar eine Fälschung (Telepolis 13.10.2012)
  20. ^ "Ancient Buddhist Statue Made of Meteorite, New Study Reveals". Science Daily. Retrieved 26 December 2012.
  21. ^ Buchner, Elmar; Schmieder, Martin; Kurat, Gero; Brandstätter, Franz; et al. (1 September 2012). "Buddha from space-An ancient object of art made of a Chinga iron meteorite fragment*". Meteoritics & Planetary Science. 47 (9): 1491–1501. Bibcode:2012M&PS...47.1491B. doi:10.1111/j.1945-5100.2012.01409.x.
  22. ^ (PDF). City of Casey. Archived from the original (PDF) on 10 May 2013. Retrieved 29 December 2012.
  23. ^ Evans, W. F. J.; Gattinger, R. L.; Slanger, T. G.; Saran, D. V.; et al. (20 November 2010). "Discovery of the FeO orange bands in the terrestrial night airglow spectrum obtained with OSIRIS on the Odin spacecraft". Geophysical Research Letters. 37 (22): L22105. Bibcode:2010GeoRL..3722105E. doi:10.1029/2010GL045310. S2CID 130887275.

External links edit

  • Pictures of the iron beads of Gerzeh and other artifacts from tomb number 67
 
Wikimedia Commons has media related to Meteoritic iron objects.

February 15, 2024
meteoric, iron, sometimes, meteoritic, iron, native, metal, early, universe, protoplanetary, disk, remnant, found, meteorites, made, from, elements, iron, nickel, mainly, form, mineral, phases, kamacite, taenite, makes, bulk, iron, meteorites, also, found, oth. Meteoric iron sometimes meteoritic iron 1 is a native metal and early universe protoplanetary disk remnant found in meteorites and made from the elements iron and nickel mainly in the form of the mineral phases kamacite and taenite Meteoric iron makes up the bulk of iron meteorites but is also found in other meteorites Apart from minor amounts of telluric iron meteoric iron is the only naturally occurring native metal of the element iron in metallic form rather than in an ore on the Earth s surface 2 Meteoric iron native iron Widmanstatten pattern on a 500g endcut from the Toluca iron meteoriteGeneralCategoryNative element mineralFormula repeating unit Fe and Ni in different ratiosSpace groupDifferent structuresIdentificationLusterMetallicDiaphaneityOpaque Contents 1 Mineralogy 1 1 Structures 2 Cultural and historical usage 2 1 Bronze Age 2 2 The Americas 2 3 Africa 2 4 Asia 3 Atmospheric phenomena 4 See also 5 References 6 External linksMineralogy editThe bulk of meteoric iron consists of taenite and kamacite Taenite is a face centered cubic and kamacite a body centered cubic iron nickel alloy Meteoric iron can be distinguished from telluric iron by its microstructure and perhaps by its chemical composition also since meteoritic iron contains more nickel and less carbon 2 Trace amounts of gallium and germanium in meteoric iron can be used to distinguish different meteorite types The meteoric iron in stony iron meteorites is identical to the gallium germanium group of the iron meteorites 3 Overview over meteoric iron mineral phases Mineral Formula Nickel Mass Ni Crystal structure Notes amp referencesAntitaenite gLow Spin Ni Fe 20 40 face centered cubic Only approved as a variety of taenite by the IMAKamacite a Fe Ni Fe0 0 9Ni0 1 5 10 body centered cubic Same structure as ferriteTaenite g Ni Fe 20 65 face centered cubic Same structure as austeniteTetrataenite FeNi 48 57 tetragonal 4 Structures edit Meteoric iron forms a few different structures that can be seen by etching or in thin sections of meteorites The Widmanstatten pattern forms when meteoric iron cools and kamacite is exsolved from taenite in the form of lamellas 5 Plessite is a more fine grained intergrowth of the two minerals in between the lamella of the Widmanstatten pattern 6 Neumann lines are fine lines running through kamacite crystals that form through impact related deformation 7 Cultural and historical usage edit nbsp A lance made from a narwhal tusk with an iron head made from the Cape York meteorite Before the advent of iron smelting meteoric iron was the only source of iron metal apart from minor amounts of telluric iron Meteoric iron was already used before the beginning of the Iron Age to make cultural objects tools and weapons 8 Bronze Age edit Iron in hieroglyphsbjꜣ n p tliterally metal of the sky Many examples of iron working from the Bronze Age have been confirmed to be meteoritic in origin 9 In ancient Egypt an iron metal bead was found in a graveyard near Gerzeh that contained 7 5 Ni 10 11 Dated to around 3200 BC geochemical analysis of the Gerzeh iron beads based on the ratio of nickel to iron and cobalt confirms that the iron was meteoritic in origin 9 Dated to around 2500 BC an iron dagger from Alaca Hoyuk was confirmed to be meteoritic in origin through geochemical analysis 9 Dated to around 2300 BC an iron pendant from Umm el Marra in Syria was confirmed to be meteoritic in origin through geochemical analysis 9 Dated to around 1400 BC an iron axe from Ugarit in Syria was found to be meteoritic in origin 9 Dated to around 1400 BC several iron axes from the Shang Dynasty in China were also confirmed to be meteoritic in origin 9 Dated to around 1350 BC an iron dagger bracelet and headrest from the tomb of Tutankhamun were confirmed to be meteoritic in origin 9 The Tutankhamun dagger consists of similar proportions of metals iron nickel and cobalt to a meteorite discovered in the area deposited by an ancient meteor shower 12 13 14 Dated to around 900 BC an iron arrowhead from Morigen in Switzerland was confirmed to be meteoritic in origin 15 The Americas edit The Inuit used parts of the Cape York meteorite to make lance heads 16 17 18 Africa edit Fragments from the Gibeon meteorite were used for centuries by the Nama people of Namibia Asia edit There are reports of the use of meteorites for manufacture of various items in Tibet see Thokcha The Iron Man a purported Tibetan Buddhist statue of Vaisravaṇa was likely carved from an ataxite meteorite 19 It has been speculated that it may be made from a fragment of the Chinga meteorite 20 21 Even after the invention of smelting meteoric iron was sometimes used where this technology was not available or metal was scarce A piece of the Cranbourne meteorite was made into a horseshoe around 1854 22 Today meteoritic iron is used in niche jewellery and knife production but most of it is used for research educational or collecting purposes Atmospheric phenomena editMeteoric iron also has an effect on the Earth s atmosphere When meteorites descend through the atmosphere outer parts are ablated Meteoric ablation is the source of many elements in the upper atmosphere When meteoric iron is ablated it forms a free iron atom that can react with ozone O3 to form FeO This FeO may be the source of the orange spectrographic bands in the spectrum of the upper atmosphere 23 See also editGlossary of meteoriticsReferences edit Rehren Thilo Belgya Tamas Jambon Albert Kali Gyorgy Kasztovszky Zsolt Kis Zoltan Kovacs Imre Maroti Boglarka Martinon Torres Marcos Miniaci Gianluca Pigott Vincent C Radivojevic Miljana Rosta Laszlo Szentmiklosi Laszlo Szokefalvi Nagy Zoltan 2013 5 000 years old Egyptian iron beads made from hammered meteoritic iron PDF Journal of Archaeological Science 40 12 4785 4792 doi 10 1016 j jas 2013 06 002 a b Fleming Stuart J Schenck Helen R 1989 History of Technology The Role of Metals UPenn Museum of Archaeology p 67 ISBN 978 0 924171 95 6 Lovering John F Nichiporuk Walter Chodos Arthur Brown Harrison 31 December 1956 The distribution of gallium germanium cobalt chromium and copper in iron and stony iron meteorites in relation to nickel content and structure Geochimica et Cosmochimica Acta 11 4 263 278 Bibcode 1957GeCoA 11 263L doi 10 1016 0016 7037 57 90099 6 Clarke Roy S Edward R D Scott 1980 Tetrataenite ordered FeNi a new mineral in meteorites PDF American Mineralogist 65 624 630 Bibcode 1980AmMin 65 624C Yang J J I Goldstein 2005 The formation of the Widmanstatten structure in meteorites Meteoritics amp Planetary Science 40 2 239 253 Bibcode 2005M amp PS 40 239Y doi 10 1111 j 1945 5100 2005 tb00378 x Goldstein J I J R Michael 2006 The formation of plessite in meteoritic metal Meteoritics amp Planetary Science 41 4 553 570 Bibcode 2006M amp PS 41 553G doi 10 1111 j 1945 5100 2006 tb00482 x Rosenhain Walter Jean McMinn 1925 The Plastic Deformation of Iron and the Formation of Neumann Lines Proceedings of the Royal Society 108 746 231 239 Bibcode 1925RSPSA 108 231R doi 10 1098 rspa 1925 0071 Waldbaum J C and James D Muhly The first archaeological appearance of iron and the transition to the iron age chapter in The coming of the age of iron Theodore A Wertme ed Yale University Press 1980 ISBN 978 0300024258 a b c d e f g Jambon Albert 2017 Bronze Age iron Meteoritic or not A chemical strategy PDF Journal of Archaeological Science 88 47 53 doi 10 1016 j jas 2017 09 008 ISSN 0305 4403 Pre Dynastic Iron Beads from Gerzeh Egypt ucl ac uk Archived from the original on 7 April 2015 Retrieved 28 December 2012 Rehren Thilo Belgya Tamas Jambon Albert Kali Gyorgy et al 31 July 2013 5 000 years old Egyptian iron beads made from hammered meteoritic iron Journal of Archaeological Science 40 12 4785 4792 doi 10 1016 j jas 2013 06 002 hdl 11568 908268 Bjorkman Judith Kingston 1973 Meteors and Meteorites in the ancient Near East Meteoritics 8 2 91 132 Bibcode 1973Metic 8 91B doi 10 1111 j 1945 5100 1973 tb00146 x Daniela Comelli Massimo D orazio Luigi Folco Mahmud El Halwagy Tommaso Frizzi Roberto Alberti Valentina Capogrosso Abdelrazek Elnaggar Hala Hassan Austin Nevin Franco Porcelli Mohamed G Rashed Gianluca Valentini 2016 The meteoritic origin of Tutankhamun s iron dagger blade Meteoritics amp Planetary Science 51 7 1301 1309 Bibcode 2016M amp PS 51 1301C doi 10 1111 maps 12664 Walsh Declan 2 June 2016 King Tut s Dagger Made of Iron From the Sky Researchers Say The New York Times Retrieved 4 June 2016 the blade s composition of iron nickel and cobalt was an approximate match for a meteorite that landed in northern Egypt The result strongly suggests an extraterrestrial origin Guy Jack 8 August 2023 Arrowhead made from meteorite 3 000 years ago found near lake in Europe CNN Retrieved 9 August 2023 Iron and steel in ancient times by Vagn Fabritius Buchwald Det Kongelige Danske Videnskabernes Selskab 2005 T A Rickard 1941 The Use of Meteoric Iron Journal of the Royal Anthropological Institute 71 1 2 55 66 doi 10 2307 2844401 JSTOR 2844401 Buchwald V F 1992 On the Use of Iron by the Eskimos in Greenland Materials Characterization 29 2 139 176 doi 10 1016 1044 5803 92 90112 U JSTOR 2844401 Der Lama mit der Hose Buddha from space ist offenbar eine Falschung Telepolis 13 10 2012 Ancient Buddhist Statue Made of Meteorite New Study Reveals Science Daily Retrieved 26 December 2012 Buchner Elmar Schmieder Martin Kurat Gero Brandstatter Franz et al 1 September 2012 Buddha from space An ancient object of art made of a Chinga iron meteorite fragment Meteoritics amp Planetary Science 47 9 1491 1501 Bibcode 2012M amp PS 47 1491B doi 10 1111 j 1945 5100 2012 01409 x The Cranbourne Meteorites PDF City of Casey Archived from the original PDF on 10 May 2013 Retrieved 29 December 2012 Evans W F J Gattinger R L Slanger T G Saran D V et al 20 November 2010 Discovery of the FeO orange bands in the terrestrial night airglow spectrum obtained with OSIRIS on the Odin spacecraft Geophysical Research Letters 37 22 L22105 Bibcode 2010GeoRL 3722105E doi 10 1029 2010GL045310 S2CID 130887275 External links editPictures of the iron beads of Gerzeh and other artifacts from tomb number 67 nbsp Wikimedia Commons has media related to Meteoritic iron objects Retrieved from https en wikipedia org w index php title Meteoric iron amp oldid 1193738590, wikipedia, wiki, book, books, library,

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