Adrian (H4) 

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Jilin (H5) 

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Miami (H5) 

• • Tomioka N., Bindi L., Okuchi T., Miyahara M., Iitaka T., Li Z., Kawatsu T., Xie X., Purevjav N, Tani R., and Kodama, Y. 2021. Poirierite, a dense metastable polymorph of magnesium iron silicate in shocked meteorites. Communications Earth & Environment 2:doi.org/10.1038/s43247-020-00090-7

  • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Novosibirsk (H5–6) 

• • Bazhan I. S., Ozawa S., Miyahara M., Ohtani E., Litasov K. D. 2017. “Spherulite-like” jadeite growth in shock-melt veins of the Novosibirsk H5/6 chondrite. Russian Geology and Geophysics 58:12–19. 

Yamato 75100 (H6) 

• • Kimura M., Suzuki A., Ohtani E., and El Goresy A. 2001. Raman petrography of high-pressure minerals in H, L, LL and E-chondrites. 64th Annual Meteoritical Society Meeting. 5261.pdf. 

  • Tomioka N. and Kimura M. 2003. The breakdown of diopside to Ca-rich majorite and glass in a shocked H chondrite. Earth and Planetary Science Letters 208:271–278.  

  • Miyahara M., Ozawa S., Ohtani E., Kimura M., Kubo T., Sakai T., Nagase T., Nishijima M., and Hirao N. Jadeite formation in shocked ordinary chondrites. 2013. Earth and Planetary Science Letters 373:102–108. 

  • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 75267 (H6) 

• • Kimura M., Chen M., Yoshida Y., El Goresy A., and Ohtani E. 2003. Back-transformation of high-pressure phases in a shock melt vein of an H-chondrite during atmospheric passage: Implications for the survival of high-pressure phases after decompression. Earth and Planetary Science Letters 217:141–150.  

Yanzhuang (H6) 

• • Xie X. D. and Chen M. 2018. Yanzhuang meteorite: mineralogy and shock metamorphism. Guangdong Science & Technology Press, Guangzhou, 202.

Asuka 880870 (L3)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 86706 (L3)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Goronyo (L4)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Mossgiel (L4)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 002825 (L4)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Grove Mountains 052049 (L5)

• • Feng L., Lin Y., Hu S., Xu L., and Miao B. 2011. Estimating compositions of natural ringwoodite in the heavily shocked Grove Mountains 052049 meteorite from Raman spectra. American Mineralogist 96:1480–1489.

La Lande (L5)

• • Xie Z., Sharp T. G., and De Carli P. S. 2006a. Estimating shock pressures based on high-pressure minerals in shock- induced melt veins of L chondrites. Meteoritics & Planetary Science 41:1883–1898.

Taiban (L5)

• • Acosta-Maeda T. E., Scott E. R. D., Sharma S. K., and Misra A. K. 2013. The pressures and temperatures of meteorite impact: Evidence from micro-Raman mapping of mineral phases in the strongly shocked Taiban ordinary chondrite. American Mineralogist 98:859–869. 

Dhofar 1970 (L5)

• • Walton E. L. and McCarthy S. 2017. Mechanisms of ringwoodite formation in shocked meteorites: Evidence from L5 chondrite Dhofar 1970. Meteoritics & Planetary Science 52:762–776.

Yamato 000552 (L5)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 000576 (L5)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 000640 (L5)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 000713 (L5)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 000973 (L5)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 001002 (L5)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 003258 (L5)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 003262 (L5)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 003262 (L5)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 003440 (L5)

• Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 003366 (L5)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 003445 (L5)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 003450 (L5)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 003465 (L5)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 003517 (L5)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 8410 (L5)

• • Kimura M., Suzuki A., Ohtani E., and El Goresy A. 2001. Raman petrography of high-pressure minerals in H, L, LL and E-chondrites. 64th Annual Meteoritical Society Meeting. 5261.pdf. 

Yamato 003262 (L5)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Acfer 040 (L5–6)

• • Sharp T. G., Lingemann C. M., Dupas C., and Stöffler D. 1997. Natural occurrence of MgSiO3 ilmenite and evidence for MgSiO3 perovskite in a shocked L chondrite. Science 277:352–355.  

  • Sharp T. G. and Hu J. 2016. Low pressure evidence of high pressures shock: Thermal histories and annealing in shocked meteorites. 79th Annual Meeting of the Meteoritical Society. 6540.pdf.  

Mbale (L5–6) 

• • Sharp T. G., Chen M., and El Goresy A. 1996. Microstructures of high-pressure minerals in shocked chondrites: Constraints on the duration of shock events. Meteoritics and Planetary Science 31:A127. 

  • Chen M., Xie X., El Goresy A., Wopenka B., and Sharp T. G. 1998. Cooling rates in the shock veins of chondrites: Constraints on the (Mg,Fe)2SiO4 polymorph transformations. Science in China 41:522–528. 

  • Sharp T. G. and Hu J. 2016. Low pressure evidence of high pressures shock: Thermal histories and annealing in shocked meteorites. 79th Annual Meeting of the Meteoritical Society 6540.pdf. 

  • Hu J., and Sharp, T. G. 2017. Back-transformation of high-pressure minerals in shocked chondrites: Low-pressure mineral evidence for strong shock. Geochimica et Cosmochimica Acta 215:277–294. 

Roy (L5–6)

• • Xie Z., Sharp T. G., and De Carli P. S. 2006. Estimating shock pressures based on high-pressure minerals in shock-induced melt veins of L chondrites. Meteoritics & Planetary Science 41:1883–1898.

Alfianello (L6)

• • Pittarello L., De Santis V., Carone L., Pratesi G., Gemmi M., Parlanti P., Steiger-Thirsfeld A., Di Michele A.l, and Giuli G. 2026. Coexisting wadsleyite and ringwoodite in the Alfianello L6 ordinary chondrite. Meteoritics & Planetary Science doi: 10.1111/maps.70134.

Alllan Hills 78003 (L6) 

• • Ohtani E., Kimura Y., Kimura M., Kubo T., and Takata T. 2006. High-pressure minerals in shocked L6-chondrites: constrains on impact conditions. Shock Waves 16:45–52. 

  • Miyahara M., El Goresy A., Ohtani E., Kimura M., Ozawa S., Nagase T., and Nishijima M. 2009. Fractional crystallization of olivine melt inclusion in shock-induced chondritic melt vein. Physics of the Earth and Planetary Interiors 177:116–121. 

Asuka 09584 (L6) 

• • Pittarello L., Ji G., Yamaguchi A., Schryvers D., Debaille V., and Claeys Ph. 2015. From olivine to ringwoodite: a TEM study of a complex process. Meteoritics & Planetary Science 50:944–957.  

  • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Asuka 87090 (L6)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Asuka 87095 (L6)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Asuka 881439 (L6)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Asuka 882003 (L6)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Asuka 9010 (L6)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Belgica 9820 (L6)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Belgica 9820 (L6)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Bursa (L6) 

• • Unsalan O. and Altunayar-Unsalan C. 2020. Shock–induced olivine–ringwoodite and plagioclase–maskelynite transformations in Bursa L6 chondrite: A Raman and ATR–FTIR spectroscopic study. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 118590.

Catherwood (L6) 

• • Coleman L. C. 1977. Ringwoodite and majorite in the Catherwood meteorite. Canadian Mineralogist 15:97–101. 

  • Madon M. and Poirier J. P. 1983. Transmission electron microscope observation of α, β and γ (Mg,Fe)2SiO4 in shocked meteorites: planar defects and polymorphic transitions. Physics of the Earth and Planetary Interiors 33:31–44. 

Château-Renard (L6)  

• • Baziotis I., Asimow P. D., Hu J., Ferrière, L., Ma C., Cernok A., Anand M., and Topa D. 2018. High pressure minerals in the Château-Renard (L6) ordinary chondrite: implications for collisions on its parent body. Scientific Reports 8: 9851. 

Coolamon (L6) 

• • Steele I. M. and Smith J. V. 1978. Coorara and Coolamon meteorites: Ringwoodite and mineralogical differences. 11th Lunar and Planetary Science Conference. pp. 1101–1103.  

Coorara (L6) 

• • Mason B., Nelen J., and White J. S. 1968. Olivine-garnet transformation in a meteorite. Science 160:66–67.

  • Smith J. V. and Mason B. 1970. Pyroxene-Garnet transformation in Coorara meteorite, Science 168:832–833.  

Dhofar 717 (L6) 

• • Litasov K. D., Badyukov D. D., and Pokhilenko N. P. 2019. Formation parameters of high-pressure minerals in the Dhofar 717 and 864 chondrite meteorites. Doklady Earth Sciences 485:327–330. 

Dhofar  864 (L6)

• • Litasov K. D., Badyukov D. D., and Pokhilenko N. P. 2019. Formation parameters of high-pressure minerals in the Dhofar 717 and 864 chondrite meteorites. Doklady Earth Sciences 485:327–330. 

Dhofar 922 (L6) 

• • Badjukov D. D., Brandstaetter F., Kurat G., Libowitzky E., and Raitala J. 2005. Ringwoodite-olivine assemblages in Dhofar 922 L6 melt veins. 48th Lunar and Planetary Science Conference 1684.pdf. 

  • Bazhan I. S., Litasov K. D., and Badyukov D. D. 2020. High-Pressure Phases in the Dhofar 922 L6 Chondrite: Crystallization of olivine–ringwoodite aggregates and jadeite from melt. Russian Geology and Geophysics, 61, 241–249.

Grove Mountains 022115 (L6)

• •  Guo Z., Li Y., Liu S., Xu H., Li S., Li X., Lin Y., Coulson I. M., and Zhang M. 2020. Discovery of nanophase iron particles and high pressure clinoenstatite in a heavily shocked ordinary chondrite: implications for the decomposition of pyroxene. Geochimica et Cosmochimica Acta 272:276–286. 

  • Xie  Z., Li Y., Zuo, S., and Si J. 2017. Major silicate phase transformations and Nano-Fe formation in shock-induced melt vein of Antarctic chondrite GRV 022115. 36th Lunar and Planetary Science Conference 2061.pdf. 

Grove Mountains 022321 (L6)

• •  Xie Z., Li X., Sharp T. G., and De Carli P. S. 2010. Ringwoodite rims around olivine cores in shock-induced melt veins of an Antarctica chondrite: Mechanisms of transformation and Fe-Mg diffusion. 73rd Annual Meteoritical Society Meeting 5184.pdf. 

Grove Mountains 052082 (L6) 

• • Feng L., Miyahara M., Nagase T., Ohtani E., Hu S., El Goresy A., and Lin Y. 2017. Shock-induced P-T conditions and formation mechanism of akimotoite-pyroxene glass assemblages in the Grove Mountains (GRV) 052082 (L6) meteorite. American Mineralogist 102:1254–1262. 

Grove Mountains 053584 (L6) 

• • Yin F., Liao Z., Hursthouse A., and Dai D. 2018. Shock-induced olivine-ringwoodite transformation in the shock vein of chondrite GRV053584. Minerals 8:139. 

Kakowa (L6) 

• • Baziotis I. P., Ma C., Guan Y., Ferrière L., Xydous S., Hu J., Kipp, M. A., Tissot, F. L. H., and Asimow P. D.  2022. Unique evidence of fluid alteration in the Kakowa (L6) ordinary chondrite. Scientific Reports, 12: 1–15.

Katol (L6) 

• • Ghosh S., Tiwari K., Miyahara M, Rohrbach A., Vollmer C., Stagno V., Ohtani E., and Ray D. 2021. Natural Fe-bearing aluminous bridgmanite in the Katol L6 chondrite, Proceedings of the National Academy of Sciences 118: e2108736118. 

Kindberg (L6) 

• • Bischoff, A., Reitze, M. P., Roszjar, J., Patzek, M., Barrat, J. A., Berndt, J.,  Di Rocco, T., Pack, A,, and Weber, I. 2025. Kindberg, the fifth meteorite fall in Austria: A weakly shocked L6 chondrite breccia with high‐pressure phases. Meteoritics & Planetary Science, doi: 10.1111/maps.70072.

Mangui (L6) 

• • Ji J., Hu S., Lin Y., Zhou Q., and Xiao Y. 2019. Petrography, mineral chemistry and shock metamorphism of the Mangui meteorite. Chinese Science Bulletin 64:579–587. 

Ness County (1894) (L6) 

• • Rubin A. E. and Read W. F. 1984. The Brownell and Ness county (1894) L6 chondrites: Further sorting-out of Ness County meteorites. Meteoritics 19:153–160.

Northwest Africa 4672 (L6) 

• • Baziotis, I., Ferriére, L., Ma, C., Hu J., Palles, D. and Asimow, P. D. 2025. New knowledge about shock events that affected the L-chondrite parent body from two heavily shocked L6 meteorite finds. Meteoritics & Planetary Science doi: 10.1111/maps.70054.

Northwest Africa 12841 (L6) 

• • Baziotis, I., Ferriére, L., Ma, C., Hu J., Palles, D. and Asimow, P. D. 2025. New knowledge about shock events that affected the L-chondrite parent body from two heavily shocked L6 meteorite finds. Meteoritics & Planetary Science doi: 10.1111/maps.70054.

Northwest Africa 4719 (L6) 

• • Kimura M., Fukuda H., Mikouchi T., Suzuki A., and Ohtani E. 2007. Abundant (Mg,Fe)SiO3 glass in shock veins in an L6 chondrite, NWA 4719. Meteoritics & Planetary Science Supplement 42:5139. 

  • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Northwest Africa 5011 (L6) 

• • Nagy S., Józsa S., Gyollai I., Bérczi S., Bendõ Z., and Stehlik H. 2011. Ringwoodite microstructures in L-chondrite NWA 5011: implications for transformation mechanism and source region in L parent body. Central European Geology 54:233–248.

  • Litasov K. D. and  Badyukov D. D. 2019. Raman spectroscopy of high-pressure phases in shocked L6 chondrite NWA 5011. Geochemistry International, 57:912–922.

Pampa del Infierno (L6) 

• • Boctor N. Z., Bell P. M., Mao H. K., and Kullerud G. 1982). Petrology and shock metamorphism of Pampa del Infierno chondrite. Geochimica et Cosmochimica Acta, 46:1903–1911. Per

Peace River (L6) 

• • Price, G. D. 1983. The nature and significance of stacking faults in wadsleyite, natural β-(Mg,Fe)2SiO4 from the Peace River meteorite. Physics of the Earth and Planetary Interiors 33:137–147. 

  • Chen M., Wopenka B., El Goresy A., and Sharp T. G. 1996. High-pressure assemblages in shock melt veins in the Peace River (L6) chondrite: Compositions and pressure-temperature history. Meteoritics and Planetary Science 31:A27.  

  • Miyahara M., El Goresy A., Ohtani E., Nagase T., Nishijima M., Vashaei Z., Ferroir T., Gillet Ph., Dubrovinsky L., and Simionovici A. 2008. Evidence for fractional crystallization of wadsleyite and ringwoodite from olivine melts in chondrules entrained in shock-melt veins. Proceedings of the National Academy of Sciences of the U.S.A. 105:8542–8547. 

Pervomaisky (L6) 

• • Bazhan I. S., Litasov K. D., Ohtani E., and Ozawa S. 2017. Majorite–olivine–high-Ca pyroxene assemblage in the shock-melt veins of Pervomaisky L6 chondrite. American Mineralogist 102:1279–1286. 

Roosevelt County 106 (L6) 

• • Sharp T. G., Xie Z., DeCarli P. S., and Hu J. 2015. A large shock vein in L chondrite Roosevelt County 106: Evidence for a long-duration shock pulse on the L chondrite parent body. Meteoritics & Planetary Science 50:1941–1953. 

Sahara 00293 (L6) 

• • Fudge C., Hu J. and Sharp T. G. 2014. The coexistence of wadsleyite and ringwoodite in L/LL chondrite SAH 293: Constraints on shock pressure conditions and olivine transformation. 45th Lunar and Planetary Science Conference. 2237.pdf.   

Sahara 98222 (L6) 

• • Ozawa S., Ohtani E., Miyahara M., Suzuki A., Kimura M., and Ito Y. 2009. Transformation textures, mechanisms of formation of high-pressure minerals in shock melt veins of L6 chondrites, and pressure-temperature conditions of the shock events. Meteoritics & Planetary Sciences 44:1771–1786. 

Sixiangkou (L6)  

• • Chen M., Sharp T. G., El Goresy A., Wopenka B., and Xie X. 1996. The majorite-pyrope + magnesiowüstite assemblage: constrains on the history of shock veins in chondrites. Science 271:1570–1573.

  • Gillet Ph., Chen M., Dubrovinsky L., and El Goresy A. 2000. Natural NaAlSi3O8-hollandite in the shocked Sixiangkou meteorite. Science 287:1633–1636. 

  • Zhang A., Hsu W., Wang R., and Ding M. 2006. Pyroxene polymorphs in melt veins of the heavily shocked Sixiangkou L6 chondrite. European Journal of Mineralogy 18:719–726. 

  • Chen M., Chen J., Xie X., and Xu J. 2007. A microstructural investigation of natural lamellar ringwoodite in olivine of the shocked Sixiangkou chondrite. Earth and Planetary Science Letters 264:277–283. 

  • Chen M. and Xie X. 2008. Two distinct assemblages of high-pressure liquidus phases in shock veins of the Sixiangkou meteorite. Meteoritics & Planetary Science 43:823–828. 

Suizhou (L6) 

• •  Xie X., Chen M., and Wang D. 2001. Shock-related mineralogical features and P-T history of the Suizhou L6 chondrite. European Journal of Mineralogy 13:1177–1190.  

  •  Xie X., Chen M., Wang D., and El Goresy A. 2001. NaAlSi3O8-hollandite and other high-pressure minerals in the shock melt veins of the Suizhou meteorite. Chinese Science Bulletin 46:1116–1125. 

  • Xie  X., Minitti M. E., Chen M., Mao H.-K., Wang D., Shu J., and Fei Y. 2002. Natural high-pressure polymorph of merrillite in the shock veins of the Suizhou meteorite. Geochimica et Cosmochimica Acta 66:2439–2444.

  • Chen M., Shu J., Xie X., and Mao H. K. 2003. Natural CaTi2O4-structured FeCr2O4 polymorph in the Suizhou meteorite and its significance in mantle mineralogy. Geochimica et Cosmochimica Acta 67:3937–3942. 

  • Chen M., Shu J., Mao H. K., Xie X., and Hemley R. J. 2003. Natural occurrence and synthesis of two new postspinel polymorphs of chromite. Proceedings of the National Academy of Sciences 100:14651–14654. 

  • Chen M., Xie X., and El Goresy A. 2004. A shock‐produced (Mg,Fe)SiO3 glass in the Suizhou meteorite. Meteoritics & Planetary Science 39:1797–1808. 

  • Chen M., El Goresy A., and Gillet P. 2004. Ringwoodite lamellae in olivine: clues to olivine-ringwoodite phase transition mechanisms in shocked meteorites and subducting slabs. Proceedings of the National Academy of Sciences of the U.S.A. 101:15033–15037. 

  • Chen M., Shu J., and Mao H. K. 2008. Xieite, a new mineral of high-pressure FeCr2O4  polymorph. Chinese Science Bulletin 53:3341–3345. 

  • Xie X., Chen M., and Wang C. 2011. Occurrence and mineral chemistry of chromite and xieite in the Suizhou L6 chondrite. Science China Earth Sciences 54:998–1010. 

  •  Xie X., Sun Z., and Chen M. 2011. The distinct morphological and petrological features of shock melt veins in the Suizhou L6 chondrite. Meteoritics & Planetary Science 46:459–469. 

  • Xie X., Zhai S., Chen M., and Yang H. 2013. Tuite, γ‐Ca3(PO4)2, formed by chlorapatite decomposition in a shock vein of the Suizhou L6 chondrite. Meteoritics & Planetary Science 48:1515–1523. 

  • Chen M. and Xie X. 2015. Shock-produced akimotoite in the Suizhou L6 chondrite. Science China Earth Sciences 58:876–880. 

  • Bindi L., Chen M., and Xie X. 2017. Discovery of the Fe-analogue of akimotoite in the shocked Suizhou L6 chondrite. Scientific Reports 7:doi:10.1038/srep42674. 

  • Bindi L., Brenker F. E., Nestola F., Koch T. E., Prior D. J., Lilly K., Krot A. N., Bizzaro M., and Xie X. 2019. Discovery of asimowite, the Fe-analog of wadsleyite, in shock-melted silicate droplets of the Suizhou L6 and the Quebrada Chimborazo 001 CB3.0 chondrites, American Mineralogist, 104:775–778. 

  • Bindi L., Shim S.-H., Sharp T. G. and Xie X. 2020. Evidence for the charge disproportionation of iron in extraterrestrial bridgmanite. Science Advances 6:eaay7893 doi: 10.1126/sciadv.aay7893. 

  • Xie X., Gu X., Yang H., Chen M., and Li K. 2020. Wangdaodeite, the LiNbO3‐structured high‐pressure polymorph of ilmenite, a new mineral from the Suizhou L6 chondrite. Meteoritics & Planetary Science, 55:184–192.

  • Tomioka N., Bindi L., Okuchi T., Miyahara M., Iitaka T., Li Z., Kawatsu T., Xie X., Purevjav N, Tani R., and Kodama, Y. 2021. Poirierite, a dense metastable polymorph of magnesium iron silicate in shocked meteorites. Communications Earth & Environment 2:doi.org/10.1038/s43247-020-00090-7.

  • Bindi L., Sinmyo R., Bykova E., Ovsyannikov S. V., McCammon C., Kupenko I., Ismailova L., Dubrovinsky L., and Xie X. 2021. Discovery of Elgoresyite,(Mg,Fe)5Si2O9: Implications for Novel Iron-Magnesium Silicates in Rocky Planetary Interiors. ACS Earth and Space Chemistry, doi/10.1021/acsearthspacechem.1c00157.

  • Xie X., Gu X.,  and Chen M. 2022. The discovery of TiO2-II, the α-PbO2-structured high-pressure polymorph of rutile, in the Suizhou L6 chondrite. Acta Geochimica, doi.org/10.1007/s11631-022-00585-4. 

  • Xie X., and Gu X. 2023. The breakdown of diopside to (Ca,Mg)SiO3 perovskite–(Mg,Ca,Fe)SiO3 glass–(Mg,Ca)SiO3 glass–(Mg,Ca)SiO3 majorite in a melt vein the Suizhou L6 chondrite. Acta Geochimica:1–12.

  • Bindi L., Xie, Z., Sharp T., and Xie X. 2024. Unveiling deep Earth’s hidden potential: insights from a new high‐pressure phase discovered in a shocked meteorite. Discover Minerals, 1:1.

Tenham (L6) 

• • Binns R. A., Davis R. J., and Reed S. J. B. 1969. Ringwoodite, natural (Mg,Fe)2SiO4 spinel in the Tenham meteorite. Nature 221:943–944. 

  • Price G. D., Putnis A., and Agrell S. O. 1979. Electron petrography of shock-produced veins in the Tenham chondrite. Contributions to Mineralogy and Petrology 71:211–218. 

  • Madon M. and Poirier J. P. 1980. Dislocations in spinel and garnet high-pressure polymorphs of olivine and pyroxene: Implications for mantle rheology. Science 207:66–68. 

  • Mori H., and Takeda H. 1985. Magnesiowustite in a shock-produced vein of the Tenham chondrite. Lunar and Planetary Science Conference 16:579–580. 

  • Putnis A., and Price G. D. 1979. High-pressure (Mg,Fe)2SiO4 phases in the Tenham chondritic meteorite. Nature 280:217–218. 

  • Price G. D., Putnis A., and Smith D. G. W. 1982. A spinel to β-phase transformation mechanism in (Mg,Fe)2SiO4. Nature 296:729–731. 

  • Madon M. and Poirier J. P. 1983. Transmission electron microscope observation of α, β and γ (Mg,Fe)2SiO4 in shocked meteorites: planar defects and polymorphic transitions. Physics of the Earth and Planetary Interiors 33:31–44. 

  • Langenhorst F., Joreau P., and Doukhan J. C. 1995. Thermal and shock metamorphism of the Tenham chondrite: A TEM examination. Geochimica et Cosmochimica Acta 59:1835–1845. 

  • Tomioka N. and Fujino K. 1997. Natural (Mg,Fe)SiO3-ilmenite and -perovskite in the Tenham meteorite. Science 277:1084–1086. 

  • Tomioka N. and Fujino, K. 1999. Akimotoite, (Mg,Fe)SiO3, a new silicate mineral of the ilmenite group in the Tenham chondrite. American Mineralogist 84:267–271. 

  • Tomioka N., Mori H., and Fujino K. 2000. Shock-induced transition of NaAlSi3O8 feldspar into a hollandite structure in a L6 chondrite. Geophysical Research Letters 27:3997–4000. 

  • Beck P., Gillet P., El Goresy A., and Mostefaoui S. 2005. Timescales of shock processes in chondritic and martian meteorites. Nature 435:1071–1074. 

  • Xie Z., Sharp T. G., and DeCarli P. S. 2006. High-pressure phases in a shock-induced melt vein of the Tenham L6 chondrite: Constraints on shock pressure and duration. Geochimica et Cosmochimica Acta 70:504–515.  

  • Xie Z., Sharp T. G., and DeCarli P. S. 2006. Estimating shock pressures based on high‐pressure minerals in shock‐induced melt veins of L chondrites. Meteoritics & Planetary Science 41:1883–1898. 

  •  Xie Z. and Sharp T. G. 2007. Host rock solid-state transformation in a shock-induced melt vein of Tenham L6 chondrite. Earth and Planetary Science Letters 254:433–445. 

  • Ferroir T., Beck P., Van de Moortèle B., Bohn M., Reynard B., Simionovici A., El Goresy A., and Gillet P. 2008. Akimotoite in the Tenham meteorite: Crystal chemistry and high-pressure transformation mechanisms. Earth and Planetary Science Letters 275:26–31. 

  • Xie Z., Sharp T. G., Leinenweber K., De Carli P. S., and Dera P. 2011. A new mineral with an olivine structure and pyroxene composition in the shock-induced melt veins of Tenham L6 chondrite. American Mineralogist 96:430–436. 

  • Tschauner O., Ma C., Beckett J. R., Prescher C., Prakapenka V. B., and Rossman G. R. 2014. Discovery of bridgmanite, the most abundant mineral in Earth, in a shocked meteorite. Science 346:1100–1102. 

  • Tomioka N., Miyahara M., and Ito M. 2016. Discovery of natural MgSiO3 tetragonal garnet in a shocked chondritic meteorite, Science Advances 2:e1501725. 

  • Tomioka, N. and Okuchi, T. 2017. A new high-pressure form of Mg2SiO4 highlighting diffusionless phase transitions of olivine. Scientific Reports 7:17351. 

  • Tomioka N., Bindi L., Okuchi T., Miyahara M., Iitaka T., Li Z., Kawatsu T., Xie X., Purevjav N, Tani R., and Kodama, Y. 2021. Poirierite, a dense metastable polymorph of magnesium iron silicate in shocked meteorites. Communications Earth & Environment 2:doi.org/10.1038/s43247-020-00090-7

Umbarger (L6) 

• • Xie Z., Tomioka N., and Sharp T. G. 2002. Natural occurrence of Fe2SiO4-spinel in the shocked Umbarger L6 chondrite. American Mineralogist 87:1257–1260.

  •  Xie Z. and Sharp T. G. 2004. High-pressure phases in shock-induced melt veins of the Umbarger L6 chondrite: Constraints of shock pressure. Meteoritics & Planetary Science 39:2043–2054. 

  • Xie Z., Sharp T. G., and De Carli P. S. 2006. Estimating shock pressures based on high-pressure minerals in shock-induced melt veins of L chondrites. Meteoritics & Planetary Science 41:1883–1898.

Villalbeto de la Peña (L6)  

• • Martinez M., Brearley A. J., Trigo‐Rodríguez J. M., and Llorca J. 2019. New observations on high‐pressure phases in a shock melt vein in the Villalbeto de la Peña meteorite: Insights into the shock behavior of diopside. Meteoritics & Planetary Science 54: 2845–2863. 

Viñales (L6)  

• • Baziotis, I. P., Xydous S., Papoutsa A., Hu, J., Ma, C., Ferriere, L., Klemme S., Berndt, J., and Asimow P. D. 2022. Investigation of the shocked Viñales ordinary chondrite (L6) meteorite fall – Implications for shock classification, fragmentation, and collision dynamics. Icarus 390:115362.

Yamato 000135 (L6)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 000893 (L6)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 74445 (L6) 

• • Miyahara M., El Goresy A., Ohtani E., Kimura M., Ozawa S., Nagase T., and Nishijima M. 2009. Fractional crystallization of olivine melt inclusion in shock-induced chondritic melt vein. Physics of the Earth and Planetary Interiors 177:116–121. 

  • Ozawa S., Ohtani E., Miyahara M., Suzuki A., Kimura M., and Ito Y. 2009. Transformation textures, mechanisms of formation of high-pressure minerals in shock melt veins of L6 chondrites, and pressure-temperature conditions of the shock events. Meteoritics & Planetary Sciences 44:1771–1786. 

Yamato 790729 (L6) 

• • Kato Y., Sekine T., Kayama M., Miyahara M., and Yamaguchi A. 2012. Collision condition indicted by high pressure phases in a chondrite. Antarctic Meteorites XXXV, E39. 

Yamato 791384 (L6) 

• • Ohtani E., Kimura Y., Kimura M., Takata T., Kondo T., and Kubo T. 2004. Formation of high-pressure minerals in shocked L6 chondrite Yamato 791384: constraints on shock conditions and parent body size. Earth and Planetary Science Letters 227:505–515. 

  • Ohtani E., Kimura Y., Kimura M., Kubo T., and Takata T. 2006. High-pressure minerals in shocked L6-chondrites: constrains on impact conditions. Shock Waves 16:45–52. 

  • Miyahara M., Ohtani E., Kimura M., El Goresy A. Ozawa S., Nagase T., Nishijima M., and Hiraga K. 2010. Coherent and subsequent incoherent ringwoodite growth in olivine of shocked L6 chondrites. Earth and Planetary Science Letters 295:321–327. 

  • Miyahara M., Ozawa S., Ohtani E., Kimura M., Kubo T., Sakai T., Nagase T., Nishijima M., and Hirao N. Jadeite formation in shocked ordinary chondrites. 2013. Earth and Planetary Science Letters 373:102–108. 

Yamato 981629 (L6)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Asuka 881199 (LL3)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 86776 (LL4)

• Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 75279 (LL4–6)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Chelyabinsk (LL5) 

• • Ozawa S., Miyahara M., Ohtani E., Koroleva O. N., Ito Y., Litasov K. D., and Pokhilenko N. P. 2014. Jadeite in Chelyabinsk meteorite and the nature of an impact event on its parent body. Scientific Reports 4: doi:10.1038/srep05033.  

Yamato 001124 (LL5)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 982630 (LL5)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 791099 (LL5–6)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 791108 (LL5–6)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Asuka 880883 (LL6)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Bates NBunataks A78004 (LL6)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Northwest Africa 757 (LL6) 

• • Bischoff A. 2002. Discovery of purple-blue ringwoodite within shock veins of an LL6 ordinary chondrite from Northwest Africa. 33rd Lunar and Planetary Science Conference. 1264.pdf. 

  • Hu J. and Sharp T. G. 2016. High-pressure phases in shock-induced melt of the unique highly shocked LL6 chondrite Northwest Africa 757. Meteoritics & Planetary Science 51:1353–1369. 

Northwest Africa 7084 (LL6) 

• Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 003198 (LL6)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 003199 (LL6)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 980321 (LL6)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Yamato 980540 (LL6)

• • Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Northwest Africa 8275 (LL7) 

• Miyahara M., Ohtani E., and Yamaguchi A. 2017. Albite dissociation reaction in the Northwest Africa 8275 shocked LL chondrite and implications for its impact history. Geochimica et Cosmochimica Acta 217:320–333.

• Miyahara M., Yamaguchi A., Saitoh M., Fukimoto K., Sakai T., Ohfuji H., Tomioka N., Kodama Y., and Ohtani, E. 2021. Systematic investigations of high‐pressure polymorphs in shocked ordinary chondrites. Meteoritics & Planetary Science 55:2619–2651.

Asuka 10164 (EH3)

• Kimura M., Yamaguchi A., and Miyahara M. 2017. Shock‐induced thermal history of an EH 3 chondrite, Asuka 10164. Meteoritics & Planetary Science, 52:24–35.

Indarch (EH4)

• Ma C. and Rubin, A.E. 2022. Zolenskyite, FeCr2S4, a new sulfide mineral from the Indarch meteorite. American Mineralogist 107:1030–1033.

Acfer 094 (ungrouped C) 

• • Vollmer C., Hoppe P., Brenker F. E., and Holzapfel C. 2007. Stellar MgSiO3 perovskite: a shock-transformed stardust silicate found in a meteorite. The Astrophysical Journal Letters 666:L49. 

Gujba (CB) 

• • Weisberg M. K. and Kimura M. 2010. Petrology and Raman spectroscopy of high-pressure phases in the Gujba CB chondrite and the shock history of the CB parent body. Meteoritics & Planetary Science 45:873–884. 

  • Miyahara M., Ohtani E., and Yamaguchi A. 2015. High-pressure polymorphs in Gujba CB type carbonaceous chondrite. Japan Geoscience Union Meeting, PPS22-20. 

Quebrada Chimborazo 001 (CB) 

• • Bindi L., Brenker F. E., Nestola F., Koch T. E., Prior D. J., Lilly K., Krot A. N., Bizzaro M., and Xie X. 2019. Discovery of asimowite, the Fe-analog of wadsleyite, in shock-melted silicate droplets of the Suizhou L6 and the Quebrada Chimborazo 001 CB3.0 chondrites, American Mineralogist 104:775–778. 

Khatyrka (CV3)  

• • Bindi L., Steinhardt P. J., Yao N., and Lu P.  J. 2011. Icosahedrite, Al63Cu24Fe13, the first natural quasicrystal. American Mineralogist, 96, 928–931.

  • Bindi L., Yao N., Lin C., Hollister L. S., MacPherson G. J., Poirier G. R., Andronicos C. L., Distler V. V., Eddy M. P., Kostin A., Kryachko V., Steinhardt W. M., and Yudovskaya M. 2014. Steinhardtite, a new body-centered-cubic allotropic form of aluminum from the Khatyrka CV3 carbonaceous chondrite. American Mineralogist 99:2433–2436. 

  • Hollister L. S., Bindi L., Yao N., Poirier G. R., Andronicos C. L., MacPherson G. J., Lin C., Distler V. V., Eddy M. P., Kostin A., Kryachko V., Steinhardt W. M., Yudovskaya M., Eiler J. M., Guan Y., Clarke J. J., and Steinhardt P. J. 2014. Impact-induced shock and the formation of natural quasicrystals in the early solar system. Nature Communications 5:4040, doi: 10.1038/ncomms5040.

  • Bindi L., Yao N., Lin C., Hollister L. S., Andronicos C. L., Distler V. V., Eddy M. P., Kostin, A., Kryachko, V., ;  MacPherson, G. J.,  Steinhardt W. M.,  Yudovskaya M., and Steinhardt P. J.  2015. Natural quasicrystal with decagonal symmetry. Scientific Reports, 5, 9111. 

  • Bindi L., Yao N., Lin C., Hollister L. S., Andronicos C. L., Distler V. V., Eddy M. P.,  Kostin, A.,  Kryachko, V., ;  MacPherson, G. J.,  Steinhardt W. M.,  Yudovskaya M., and Steinhardt P. J. 2015. Decagonite, Al71Ni24Fe5, a quasicrystal with decagonal symmetry from the Khatyrka CV3 carbonaceous chondrite. American Mineralogist, 100, 2340–2343.

  • Bindi L., Pham J., and Steinhardt P.  J. 2018. Previously unknown quasicrystal periodic approximant found in space. Scientific Reports, 8, 1–7.