High-pressure minerals in impact structures
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Chao E. C., Shoemaker E. M., and Madsen B. M. 1960. First natural occurrence of coesite. Science 132:220–222.
Chao E. C. T., Fahey J. J., Littler J., and Milton D. J. 1962. Stishovite, SiO2, a very high pressure new mineral from Meteor Crater, Arizona. Journal of Geophysical Research 67:419–421.
Gurov Y. P., Val’ter A. A., and Rakitskaya R. B. 1980. Coesite in rocks of meteorite explosion craters on the Ukranian shield. International Geology Review 22:329–332.
McCone J. F., Fries, M. D., Killgore M, 2008. Raman detection of titania-II, an impact induced rutile polymorph in suevite ejecta at Bosumtwi crater, Ghana. Lunar Planet. Sci. XXXIX, Abstract #2450.
Ferrière L., Koeberl C., and Reimold W. U. 2009. Characterisation of ballen quartz and cristobalite in impact breccias: new observations and constraints on ballen formation. European Journal of Mineralogy 21:203–217.
Jackson J. C., Horton J. W., Chou I., and Belkin H. E. 2006. A shock-induced polymorph of anatase and rutile from the Chesapeake Bay impact structure, Virginia, USA. American Mineralogist 91:604–608.
Malone L., Boonsue S., Spray J., and Wittmann A. 2010. Zircon-Reidite Relations in Breccias from the Chesapeake Bay Impact Structure. In Lunar and Planetary Science Conference (Vol. 41, p. 2286).
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Gurov E. P. and Koeberl C. 2004. Shocked rocks and impact glasses from the El'gygytgyn impact structure, Russia. Meteoritics & Planetary Science 39:1495–1508.
Dead Sea
Britvin S. N., Vereschchagin O. S., Shilovskikh V. V., Krzhizhanovskaya M. G., Gorelova L. A., Vlasenko N. S., Pakhomova A. S., Zaitsev A. N., Zolotarev A. A., Bykov M, Lozhkin M. S. and Nestola F.. 2021. Discovery of terrestrial allabogdanite (Fe, Ni)2P, and the effect of Ni and Mo substitution on the barringerite-allabogdanite high-pressure transition. American Mineralogist 106: 944–952.
Osinski G. R. 2007. Impact metamorphism of CaCO3-bearing sandstones at the Haughton structure, Canada. Meteoritics & Planetary Science 42:1945–1960.
Bunch T. E. and Cohen A. J. 1963. Coesite and shocked quartz from Holleford crater, Ontario, Canada. Science 142:379–381.
Fazio A., Folco L., D’Orazio M., Frezzotti M. L., and Cordier C. 2014. Shock metamorphism and impact melting in small impact craters on Earth: Evidence from Kamil crater, Egypt. Meteoritics & Planetary Science 49:2175–2200.
Campanale F., Mugnaioli E., Gemmi M., and Folco L. 2021. The formation of impact coesite. Scientific Reports 11:1–8.
Vishnevskiy S. A., Maslov M. A., Pal’chik N. A., and Ponomarev G. Y. 1977. Coesite in the rocks of the Kara Structure. Doklady Akademii Nauk SSSR 232:154–157.
Cohen A. J., Bunch T. E., and Reid A. M. 1961. Coesite discoveries establish cryptovolcanics as fossil meteorite craters. Science 134:1624–1625.
Gurov Y. P., Val’ter A. A., and Rakitskaya R. B. 1980. Coesite in rocks of meteorite explosion craters on the Ukranian shield. International Geology Review 22:329–332.
Lehtinen M. 1976. Lake Lappajärvi, a meteorite impact site in Western Finland. Geological Survey of Finland Bulletin 282:1–92.
Agarwal A., Reznik B., Kontny A., Heissler S., and Schilling F. 2016. Lingunite-a high-pressure plagioclase polymorph at mineral interfaces in doleritic rock of the Lockne impact structure (Sweden). Scientific Reports 6. doi:10.1038/srep25991
Jaret S. J., Phillips B. L., King D. T., Glotch T. D., Rahman Z., and Wright S. P. 2016. An unusual occurrence of coesite at the Lonar crater, India. Meteoritics & Planetary Science 52:147–163.
Svensson N. B. and Wickman F. E. 1965. Coesite from Lake Mien, Southern Sweden. Nature 205:1202–1203.
Muong Phin, Laos
Glass B. P., Folco L., Masotta, M., and Campanal, F. 2020. Coesite in a Muong Nong‐type tektite from Muong Phin, Laos: Description, formation, and survival. Meteoritics & Planetary Science.
Gurov Y. P., Val’ter A. A., and Rakitskaya R. B. 1980. Coesite in rocks of meteorite explosion craters on the Ukranian shield. International Geology Review 22:329–332.
Vishnevskii S. A., Kovaleva L. T., and Pal'chik N. A. 1974. Coesite in the rocks of the Popigai structure. Geologiya i Geofizika 15:140–145.
Vishnevskii S. A., Dolgov Y. A., Kovaleva L. T., and Palchik, N. 1975. Stishovite in rocks of Popigai structure. Doklady Akademii Nauk SSSR 221:1167.
Koeberl C., Masaitis V. L., Shafranovsky G. I., Gilmour I., Langenhorst F., and Schrauder M. 1997. Diamonds from the Popigai impact structure, Russia. Geology 25:967–970.
Ohfuji H., Irifune T., Litasov K. D., Yamashita T., Afanasiev V. P., and Pokhilenko N. P. 2013. Microtexture and formation mechanism of impact diamonds from the Popigai crater, Russia. Crystallogenesis and Mineralogy: 279.
Goryainov S. V., Likhacheva A. Y., Rashchenko S. V., Shubin A. S., Afanas' ev V. P., and Pokhilenko N. P. 2014. Raman identification of lonsdaleite in Popigai impactites. Journal of Raman Spectroscopy 45:305–313.
Ohfuji H., Irifune T., Litasov K. D., Yamashita T., Isobe F., Afanasiev V. P., and Pokhilenko N. P. 2015. Natural occurrence of pure nano-polycrystalline diamond from impact crater. Scientific reports 5:14702.
Ramgarh
Ray D., Misra S., Upadhyay D., Newsom H. E., Peterson E. J. Dube A., and Satyanaryanan M. 2020. Iron-nickel metallic components bearing silicate-melts and coesite from Ramgarh impact structure, west-central India: Possible identification of the impactor. Journal of Earth System Science, 129, 118.
El Goresy A. and Donnay G. 1968. A new allotropic form of carbon from the Ries crater. Science 161:363–364.
James O. B. 1969. Jadeite: shock-induced formation from oligoclase, Ries Crater, Germany. Science 165:1005–1008.
Stöffler D. 1971. Coesite and stishovite in shocked crystalline rocks. Journal of Geophysical Research 76:5474–5488.
Hough R. M., Gilmour I., Pillinger C. T., and Arden J. W. 1995. Diamond and silicon carbide in impact melt rock from the Ries impact crater. Nature 378:41–44.
El Goresy A., Chen M., Dubrovinsky L., Gillet P., and Graup G. 2001. An ultradense polymorph of rutile with seven-coordinated titanium from the Ries crater. Science 293:1467–1470.
El Goresy A., Chen M., Gillet P., Dubrovinsky L., Graup G., and Ahuja R. 2001. A natural shock-induced dense polymorph of rutile with α-PbO2 structure in the suevite from the Ries crater in Germany. Earth and Planetary Science Letters 192:485–495.
El Goresy A., Dubrovinsky L. S., Gillet P., Mostefaoui S., Graup G., Drakopoulos M., Simionovici, A. S., Swamy V. S., and Masaitis V. L. 2003. A new natural, super-hard, transparent polymorph of carbon from the Popigai impact crater, Russia. Comptes Rendus Geoscience, 335:889–898.
Gucsik A., Koeberl C., Brandstätter F., Libowitzky E., and Reimold W. U. 2004. Cathodoluminescence, electron microscopy, and Raman spectroscopy of experimentally shock metamorphosed zircon crystals and naturally shocked zircon from the Ries impact crater. In Cratering in marine environments and on ice (pp. 281–322). Springer, Berlin, Heidelberg.
Stähle V., Altherr R., Koch M., and Nasdala L. 2008. Shock-induced growth and metastability of stishovite and coesite in lithic clasts from suevite of the Ries impact crater (Germany). Contributions to Mineralogy and Petrology 155:457–472.
Dubrovinsky L. S., El Goresy A., Gillet P., Wu X., and Simionivici A. 2009. A novel natural shock-induced high-pressure polymorph of FeTiO3 with the Li-Niobate Structure from the Ries Crater, Germany. Meteoritics & Planetary Science Supplement 72:5094.
El Goresy A., Dubrovinsky L., Gillet P., Graup G., and Chen M. 2010. Akaogiite: An ultra-dense polymorph of TiO2 with the baddeleyite-type structure, in shocked garnet gneiss from the Ries Crater, Germany. American Mineralogist 95:892–895.
Stähle V., Altherr R., Nasdala L., and Ludwig T. 2011. Ca-rich majorite derived from high-temperature melt and thermally stressed hornblende in shock veins of crustal rocks from the Ries impact crater (Germany). Contributions to Mineralogy and Petrology 161:275-291.
Erickson T. M., Pearce M. A., Reddy S. M., Timms N. E., Cavosie A. J., Bourdet J., Rickard W. D. A., and Nemchin A. A. 2017. Microstructural constraints on the mechanisms of the transformation to reidite in naturally shocked zircon. Contributions to Mineralogy and Petrology 172:6.
Stähle V., Altherr R., Nasdala L., Trieloff M., and Varychev A. 2017. Majoritic garnet grains within shock-induced melt veins in amphibolites from the Ries impact crater suggest ultrahigh crystallization pressures between 18 and 9 GPa. Contributions to Mineralogy and Petrology 172:86.
Tschauner O., Ma C., Lanzirotti A., and Newville M. G. 2020. Riesite, a new high pressure polymorph of TiO2 from the Ries impact structure. Minerals 10:78.
Stähle, V., Chutimun Chanmuang N., Schwarz W. H., Trieloff M.,Varychev, A. 2022. Newly detected shock‐induced high‐pressure phases formed in amphibolite clasts of the suevite breccia (Ries impact crater, Germany): Liebermannite, kokchetavite, and other ultrahigh‐pressure phases, Contributions to Mineralogy and Petrology, 177:80.
Plan A., Kenny G. G., Erickson T. M., Lindgren P., Alwmark C., Holm‐Alwmark S., Lambert P., Schersten A., and Söderlund U. 2021. Exceptional preservation of reidite in the Rochechouart impact structure, France: New insights into shock deformation and phase transition of zircon. Meteoritics & Planetary Science (in press)
Cavosie A. J., Erickson T. M., and Timms N. E. 2015. Nanoscale records of ancient shock deformation: Reidite (ZrSiO4) in sandstone at the Ordovician Rock Elm impact crater. Geology 43:315–318.
Cohen A. J., Bunch T. E., and Reid A. M. 1961. Coesite discoveries establish cryptovolcanics as fossil meteorite craters. Science 134:1624–1625.
Martini J. E. J. 1978. Coesite and stishovite in the Vredefort dome, South Africa. Nature 272:715–717.
Martini J. E. J. 1991. The nature, distribution and genesis of the coesite and stishovite associated with the pseudotachylite of the Vredefort Dome, South Africa. Earth and Planetary Science Letters 103:285–300.
Martini J. E. J. 1992. The metamorphic history of the Vredefort dome at approximately 2 Ga as revealed by coesite‐stishovite‐bearing pseudotachylites. Journal of Metamorphic Geology 10:517–527.
Leroux H., Reimold W. U., and Doukhan J. C. 1994. A TEM investigation of shock metamorphism in quartz from the Vredefort dome, South Africa. Tectonophysics 230:223–239.
Spray J. G. and Boonsue S. 2018. Quartz–coesite–stishovite relations in shocked metaquartzites from the Vredefort impact structure, South Africa. Meteoritics & Planetary Science 1:93–109.
Masaytis V. L., Mashchak M. S., and Sokolova I. Y. 1980. High pressure silica phases in the Ternovka Astrobleme. Doklady Akademii Nauk SSSR 255:164–167.
Chao E. T. C., Fahey J. J., and Littler J. 1961. Coesite from Wabar Crater, near Al Hadida, Arabia. Science 133:882–883.
Dence M. R., Robertson P. B., and Wirthlin R. L. 1974. Coesite from the Lake Wanapitei crater, Ontario. Earth and Planetary Science Letters 22:118–122.
Cox M. A., Cavosie A. J., Bland P. A., Miljković, K., and Wingate M. T. 2018. Microstructural dynamics of central uplifts: Reidite offset by zircon twins at the Woodleigh impact structure, Australia. Geology 46:983–986.
Chen M., Xiao W., and Xie X. 2010. Coesite and quartz characteristic of crystallization from shock-produced silica melt in the Xiuyan crater. Earth and Planetary Science Letters 297:306–314.
Chen M., Yin F., Li X., Xie X., Xiao W., and Tan D. 2013. Natural occurrence of reidite in the Xiuyan crater of China. Meteoritics & Planetary Science 48:796–805.
Chen M., Gu X. P., Xie X. D., Yin F., 2013. High-pressure polymorph of TiO2-II from the Xiuyan crater of China. Chinese Science Bulletin. 58, 4655–4662.
Chen M., Shu J., Xie X. and Tan D. 2019. Maohokite, a post‐spinel polymorph of MgFe2O4 in shocked gneiss from the Xiuyan crater in China. Meteoritics & Planetary Science, 54:495–502.
Yin F., Sharp T. G., and Chen M. 2021. Nanotextures and formation process of coesite in silica glass from the Xiuyan impact crater. Meteoritics & Planetary Science, 56: 1212–1223.
Yilan
Chen M., Koeberl C., Tan D., Ding P., Xiao W., Wang N., Chen Y., and Xie X. 2021. Yilan crater, China: Evidence for an origin by meteorite impact. Meteoritics & Planetary Science 56:1274–1292.
Gurov E. P., Gurova E. P., and Rakitskaya R. B. 1995. Impact diamonds in the craters of the Ukrainian shield. Meteoritics 30:515.