Log InRegister
Home PageAbout MindatThe Mindat ManualHistory of MindatCopyright StatusWho We AreContact UsAdvertise on Mindat
Donate to MindatCorporate SponsorshipSponsor a PageSponsored PagesMindat AdvertisersAdvertise on Mindat
Learning CenterWhat is a mineral?The most common minerals on earthInformation for EducatorsMindat ArticlesThe ElementsBooks & Magazines
Minerals by PropertiesMinerals by ChemistryAdvanced Locality SearchRandom MineralRandom LocalitySearch by minIDLocalities Near MeSearch ArticlesSearch GlossaryMore Search Options
Search For:
Mineral Name:
Locality Name:
Keyword(s):
 
The Mindat ManualAdd a New PhotoRate PhotosLocality Edit ReportCoordinate Completion ReportAdd Glossary Item
Mining CompaniesStatisticsUsersMineral MuseumsMineral Shows & EventsThe Mindat DirectoryDevice Settings
Photo SearchPhoto GalleriesNew Photos TodayNew Photos YesterdayMembers' Photo GalleriesPast Photo of the Day GalleryMineral Photography

Zhushan Co., Shiyan, Hubei, Chinai
Regional Level Types
Zhushan Co.County
ShiyanPrefecture
HubeiProvince
ChinaCountry

This page is currently not sponsored. Click here to sponsor this page.
Key


No description has been added for this locality. Can you add one?

Select Mineral List Type

Standard Detailed Strunz Dana Chemical Elements

Mineral List

Mineral list contains entries from the region specified including sub-localities

47 valid minerals.

Rock Types Recorded

Note: this is a very new system on mindat.org and data is currently VERY limited. Please bear with us while we work towards adding this information!

Rock list contains entries from the region specified including sub-localities

Select Rock List Type

Alphabetical List Tree Diagram

Detailed Mineral List:

Acanthite
Formula: Ag2S
Reference: Congqiang Liu (1987): Mineral Deposits 6(4), 53-61; Tianwei Guo and Zhongwen Han (1990): Northeastern Geological Science and Technology Information 11(2), 1-11; Dongbo Wang, Benren Zhang, Zhendong Ma, Dekun Huang, and Yuanwen Lin (1991): Geology and Prospecting 27(8), 44-50; Shihe Lei, Guiying Tang, Zhengyong Qin, Zicai Zhang, and Bo Liu (1998): Geology and Prospecting 34(4), 13-19
Aegirine
Formula: NaFe3+Si2O6
Reference: Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
Albite
Formula: Na(AlSi3O8)
Reference: Congqiang Liu (1987): Mineral Deposits 6(4), 53-61; Tianwei Guo and Zhongwen Han (1990): Northeastern Geological Science and Technology Information 11(2), 1-11; Wenbo Li, Weidong Zhou, Shichang Chen, Yingping Li, Xiaohua Deng, and Richen Zhong (2010): Earth Science Frontiers 17(1), 177-185
'Albite-Anorthite Series'
Reference: Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
'Alkali Feldspar'
Reference: Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
'Allanite Group'
Formula: {A12+REE3+}{M3+2M32+}(Si2O7)(SiO4)O(OH)
Reference: Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
Amesite
Formula: Mg2Al(AlSiO5)(OH)4
Reference: Shihe Lei, Guiying Tang, Zhengyong Qin, Zicai Zhang, and Bo Liu (1998): Geology and Prospecting 34(4), 13-19
'Amphibole Supergroup'
Formula: AX2Z5((Si,Al,Ti)8O22)(OH,F,Cl,O)2
Reference: Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
'Ancylite'
Reference: Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
Ankerite
Formula: Ca(Fe2+,Mg)(CO3)2
Baryte
Formula: BaSO4
Barytocalcite
Formula: BaCa(CO3)2
Reference: Lü Zhi-cheng, Liu Cong-qiang, Liu Jia-jun, and Wu Feng-chang (2004): Progress in Natural Science 14(10), 889-895.
'Bastnäsite'
Reference: Orris, G.J., and Grauch, R.I. (2002): USGS Open-File Report 02-189, 174 pp.; Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
Bastnäsite-(Ce)
Formula: Ce(CO3)F
Reference: Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.; Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
'Biotite'
Formula: K(Fe2+/Mg)2(Al/Fe3+/Mg)([Si/Al]Si2O10)(OH/F)2
Bornite
Formula: Cu5FeS4
Reference: Congqiang Liu (1987): Mineral Deposits 6(4), 53-61
Burbankite
Formula: (Na,Ca)3(Sr,Ba,Ce)3(CO3)5
Reference: Orris, G.J., and Grauch, R.I. (2002): USGS Open-File Report 02-189, 174 pp.
Calcite
Formula: CaCO3
Chalcopyrite
Formula: CuFeS2
Reference: Congqiang Liu (1987): Mineral Deposits 6(4), 53-61; Dongbo Wang, Benren Zhang, Zhendong Ma, Dekun Huang, and Yuanwen Lin (1991): Geology and Prospecting 27(8), 44-50; Shihe Lei, Guiying Tang, Zhengyong Qin, Zicai Zhang, and Bo Liu (1998): Geology and Prospecting 34(4), 13-19
'Chevkinite Group'
Reference: Zhang Peishan, Yang Zhuming, Tao Kejie, and Yang Xueming (1996): "Mineralogy and Geology of Rare Earths in China", Science Press (Beijing), 226 pp.
'Chlorite Group'
Columbite-(Fe)
Formula: Fe2+Nb2O6
Reference: Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
'Columbite-(Fe)-Columbite-(Mn) Series'
Reference: Shi Li (1980): Geochimica 9(4), 345-355; Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
Crandallite
Formula: CaAl3(PO4)(PO3OH)(OH)6
Reference: Zhenrong Shi (2008): Jiangsu Geology 32(2), 109-112
Diopside
Formula: CaMgSi2O6
Reference: Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
Dolomite
Formula: CaMg(CO3)2
Dolomite var: Ferroan Dolomite
Formula: Ca(Mg,Fe)(CO3)2
Reference: Orris, G.J., and Grauch, R.I. (2002): USGS Open-File Report 02-189, 174 pp.
'Electrum'
Formula: (Au,Ag)
Fersmite
Formula: (Ca,Ce,Na)(Nb,Ta,Ti)2(O,OH,F)6
Reference: Shi Li (1980): Geochimica 9(4), 345-355; Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
Fluorapatite
Formula: Ca5(PO4)3F
Reference: Orris, G.J., and Grauch, R.I. (2002): USGS Open-File Report 02-189, 174 pp.; Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.; Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
Fluorite
Formula: CaF2
Reference: Orris, G.J., and Grauch, R.I. (2002): USGS Open-File Report 02-189, 174 pp.
Galena
Formula: PbS
Reference: Congqiang Liu (1987): Mineral Deposits 6(4), 53-61; Dongbo Wang, Benren Zhang, Zhendong Ma, Dekun Huang, and Yuanwen Lin (1991): Geology and Prospecting 27(8), 44-50; Shihe Lei, Guiying Tang, Zhengyong Qin, Zicai Zhang, and Bo Liu (1998): Geology and Prospecting 34(4), 13-19
Gold
Formula: Au
Graphite
Formula: C
Reference: Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
Hotsonite
Formula: Al11(SO4)3(PO4)2(OH)21 · 16H2O
Reference: Zhenrong Shi, Keqin Cai, and Mingquan Gong (2008): Northwestern Geology 45(2), 56-62
Ilmenite
Formula: Fe2+TiO3
Reference: Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
Jalpaite
Formula: Ag3CuS2
Reference: Shihe Lei, Guiying Tang, Zhengyong Qin, Zicai Zhang, and Bo Liu (1998): Geology and Prospecting 34(4), 13-19
'K Feldspar'
Magnetite
Formula: Fe2+Fe3+2O4
Reference: Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
Microcline
Formula: K(AlSi3O8)
Reference: Wu, C., Yuan, Z., and Bai, G. (1996): Rare earth deposits in China. In: Jones, A.P., Wall, F., and Williams, C.T. (Eds.): Rare Earth Minerals: Chemistry, origin and ore deposits. The Mineralogical Society Series, Vol. 7. Chapman & Hall (London).
'Monazite'
Reference: Orris, G.J., and Grauch, R.I. (2002): USGS Open-File Report 02-189, 174 pp.; Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
Monazite-(Ce)
Formula: Ce(PO4)
Reference: Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
Muscovite
Formula: KAl2(AlSi3O10)(OH)2
Muscovite var: Sericite
Formula: KAl2(AlSi3O10)(OH)2
'Nioboaeschynite'
Reference: Shi Li (1980): Geochimica 9(4), 345-355
Nioboaeschynite-(Ce)
Formula: (Ce,Ca)(Nb,Ti)2(O,OH)6
Reference: Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
'Parisite'
Reference: Orris, G.J., and Grauch, R.I. (2002): USGS Open-File Report 02-189, 174 pp.
Parisite-(Ce)
Formula: CaCe2(CO3)3F2
Reference: Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
Pearceite
Formula: [Ag9CuS4][(Ag,Cu)6(As,Sb)2S7]
Reference: Congqiang Liu (1987): Mineral Deposits 6(4), 53-61
Perovskite
Formula: CaTiO3
Reference: Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
Proustite
Formula: Ag3AsS3
Reference: Tianwei Guo and Zhongwen Han (1990): Northeastern Geological Science and Technology Information 11(2), 1-11
Pyrargyrite
Formula: Ag3SbS3
Reference: Tianwei Guo and Zhongwen Han (1990): Northeastern Geological Science and Technology Information 11(2), 1-11
Pyrite
Formula: FeS2
'Pyrochlore'
Reference: Shi Li (1980): Geochimica 9(4), 345-355
'Pyrochlore Group'
Formula: A2Nb2(O,OH)6Z
Reference: Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
'Pyrochlore Supergroup'
Formula: A2-mD2X6-wZ1-n
Reference: Berger, V.I., Singer, D.A., and Orris, G.J. (2009): USGS Open-File Report 09-1139
'Pyrochlore Supergroup var: Betafite (of Hogarth 1977)'
Formula: (Ca,Na,U)2(Ti, Nb,Ta)2O6Z(OH)
Reference: Berger, V.I., Singer, D.A., and Orris, G.J. (2009): USGS Open-File Report 09-1139
Pyrrhotite
Formula: Fe7S8
Reference: Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
Quartz
Formula: SiO2
Rutile
Formula: TiO2
Reference: Berger, V.I., Singer, D.A., and Orris, G.J. (2009): USGS Open-File Report 09-1139; Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.; Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.; Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
Rutile var: Ilmenorutile
Formula: Fex(Nb,Ta)2x · 4Ti1-xO2
Reference: Shi Li (1980): Geochimica 9(4), 345-355
Rutile var: Niobian Rutile
Formula: (Ti,Nb)O2
Reference: Orris, G.J., and Grauch, R.I. (2002): USGS Open-File Report 02-189, 174 pp.
Silver
Formula: Ag
Reference: Congqiang Liu (1987): Mineral Deposits 6(4), 53-61; Tianwei Guo and Zhongwen Han (1990): Northeastern Geological Science and Technology Information 11(2), 1-11; Dongbo Wang, Benren Zhang, Zhendong Ma, Dekun Huang, and Yuanwen Lin (1991): Geology and Prospecting 27(8), 44-50; Shihe Lei, Guiying Tang, Zhengyong Qin, Zicai Zhang, and Bo Liu (1998): Geology and Prospecting 34(4), 13-19
Silver var: Küstelite
Formula: Ag
Reference: Congqiang Liu (1987): Mineral Deposits 6(4), 53-61; Tianwei Guo and Zhongwen Han (1990): Northeastern Geological Science and Technology Information 11(2), 1-11; Dongbo Wang, Benren Zhang, Zhendong Ma, Dekun Huang, and Yuanwen Lin (1991): Geology and Prospecting 27(8), 44-50
Sphalerite
Formula: ZnS
Stromeyerite
Formula: AgCuS
Reference: Congqiang Liu (1987): Mineral Deposits 6(4), 53-61
Synchysite-(Ce)
Formula: CaCe(CO3)2F
Reference: Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
'Tetrahedrite'
Formula: Cu6(Cu4X2)Sb4S13
Reference: Congqiang Liu (1987): Mineral Deposits 6(4), 53-61; Tianwei Guo and Zhongwen Han (1990): Northeastern Geological Science and Technology Information 11(2), 1-11; Dongbo Wang, Benren Zhang, Zhendong Ma, Dekun Huang, and Yuanwen Lin (1991): Geology and Prospecting 27(8), 44-50; Shihe Lei, Guiying Tang, Zhengyong Qin, Zicai Zhang, and Bo Liu (1998): Geology and Prospecting 34(4), 13-19
'Tetrahedrite var: Argentian Tetrahedrite'
Formula: (Cu,Ag)6[Cu4(Fe,Zn)2]Sb4S13
Reference: Congqiang Liu (1987): Mineral Deposits 6(4), 53-61; Tianwei Guo and Zhongwen Han (1990): Northeastern Geological Science and Technology Information 11(2), 1-11; Dongbo Wang, Benren Zhang, Zhendong Ma, Dekun Huang, and Yuanwen Lin (1991): Geology and Prospecting 27(8), 44-50; Shihe Lei, Guiying Tang, Zhengyong Qin, Zicai Zhang, and Bo Liu (1998): Geology and Prospecting 34(4), 13-19
Turquoise
Formula: Cu(Al,Fe3+)6(PO4)4(OH)8 · 4H2O
'Viséite'
Reference: Zhenrong Shi, Keqin Cai, and Mingquan Gong (2008): Northwestern Geology 45(2), 56-62
Witherite
Formula: BaCO3
Reference: Lü Zhi-cheng, Liu Cong-qiang, Liu Jia-jun, Zhao Zhi-qi, Wu Feng-chang, and Li Jian (2005): Geochimica 34(6), 557-573.
Woodhouseite
Formula: CaAl3(PO4)(SO4)(OH)6
Colour: Blue
Reference: Zhenrong Shi (2008): Jiangsu Geology 32(2), 109-112
Zircon
Formula: Zr(SiO4)
Reference: Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.; Li, S. (1982). Geochemical features and petrogenesis of Miaoya carbonatites, Hubei Province. Geochemistry, 1(4), 409-420. Xu, C., Kynicky, J., Chakhmouradian, A. R., Li, X., & Song, W. (2015). A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen: Miaoya rare-metal deposit, central China. Lithos, 227, 107-121. Xu, C., Kynicky, J., Chakhmouradian, A. R., Campbell, I. H., & Allen, C. M. (2010). Trace-element modeling of the magmatic evolution of rare-earth-rich carbonatite from the Miaoya deposit, Central China. Lithos, 118(1-2), 145-155. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.

List of minerals arranged by Strunz 10th Edition classification

Group 1 - Elements
'Electrum'1.AA.05(Au,Ag)
Gold1.AA.05Au
Graphite1.CB.05aC
Silver1.AA.05Ag
var: Küstelite1.AA.05Ag
Group 2 - Sulphides and Sulfosalts
Acanthite2.BA.35Ag2S
Bornite2.BA.15Cu5FeS4
Chalcopyrite2.CB.10aCuFeS2
Galena2.CD.10PbS
Jalpaite2.BA.45Ag3CuS2
Pearceite2.GB.15[Ag9CuS4][(Ag,Cu)6(As,Sb)2S7]
Proustite2.GA.05Ag3AsS3
Pyrargyrite2.GA.05Ag3SbS3
Pyrite2.EB.05aFeS2
Pyrrhotite2.CC.10Fe7S8
Sphalerite2.CB.05aZnS
Stromeyerite2.BA.40AgCuS
'Tetrahedrite'2.GB.05Cu6(Cu4X2)Sb4S13
'var: Argentian Tetrahedrite'2.GB.05(Cu,Ag)6[Cu4(Fe,Zn)2]Sb4S13
Group 3 - Halides
Fluorite3.AB.25CaF2
Group 4 - Oxides and Hydroxides
Columbite-(Fe)4.DB.35Fe2+Nb2O6
Fersmite4.DG.05(Ca,Ce,Na)(Nb,Ta,Ti)2(O,OH,F)6
Ilmenite4.CB.05Fe2+TiO3
Magnetite4.BB.05Fe2+Fe3+2O4
Nioboaeschynite-(Ce)4.DF.05(Ce,Ca)(Nb,Ti)2(O,OH)6
Perovskite4.CC.30CaTiO3
'Pyrochlore Group'4.00.A2Nb2(O,OH)6Z
Quartz4.DA.05SiO2
Rutile4.DB.05TiO2
var: Ilmenorutile4.DB.05Fex(Nb,Ta)2x · 4Ti1-xO2
var: Niobian Rutile4.DB.05(Ti,Nb)O2
Group 5 - Nitrates and Carbonates
Ankerite5.AB.10Ca(Fe2+,Mg)(CO3)2
Barytocalcite5.AB.45BaCa(CO3)2
Bastnäsite-(Ce)5.BD.20aCe(CO3)F
Burbankite5.AC.30(Na,Ca)3(Sr,Ba,Ce)3(CO3)5
Calcite5.AB.05CaCO3
Dolomite5.AB.10CaMg(CO3)2
var: Ferroan Dolomite5.AB.10Ca(Mg,Fe)(CO3)2
Parisite-(Ce)5.BD.20bCaCe2(CO3)3F2
Synchysite-(Ce)5.BD.20cCaCe(CO3)2F
Witherite5.AB.15BaCO3
Group 7 - Sulphates, Chromates, Molybdates and Tungstates
Baryte7.AD.35BaSO4
Group 8 - Phosphates, Arsenates and Vanadates
Crandallite8.BL.10CaAl3(PO4)(PO3OH)(OH)6
Fluorapatite8.BN.05Ca5(PO4)3F
Hotsonite8.DF.05Al11(SO4)3(PO4)2(OH)21 · 16H2O
Monazite-(Ce)8.AD.50Ce(PO4)
Turquoise8.DD.15Cu(Al,Fe3+)6(PO4)4(OH)8 · 4H2O
Woodhouseite8.BL.05CaAl3(PO4)(SO4)(OH)6
Group 9 - Silicates
Aegirine9.DA.25NaFe3+Si2O6
Albite9.FA.35Na(AlSi3O8)
Amesite9.ED.15Mg2Al(AlSiO5)(OH)4
Diopside9.DA.15CaMgSi2O6
Microcline9.FA.30K(AlSi3O8)
Muscovite9.EC.15KAl2(AlSi3O10)(OH)2
var: Sericite9.EC.15KAl2(AlSi3O10)(OH)2
Zircon9.AD.30Zr(SiO4)
Unclassified Minerals, Rocks, etc.
'Albite-Anorthite Series'-
'Alkali Feldspar'-
'Allanite Group'-{A12+REE3+}{M3+2M32+}(Si2O7)(SiO4)O(OH)
'Amphibole Supergroup'-AX2Z5((Si,Al,Ti)8O22)(OH,F,Cl,O)2
'Ancylite'-
'Bastnäsite'-
'Biotite'-K(Fe2+/Mg)2(Al/Fe3+/Mg)([Si/Al]Si2O10)(OH/F)2
'Chevkinite Group'-
'Chlorite Group'-
'Columbite-(Fe)-Columbite-(Mn) Series'-
'K Feldspar'-
'Monazite'-
'Nioboaeschynite'-
'Parisite'-
'Pyrochlore'-
'Pyrochlore Supergroup'-A2-mD2X6-wZ1-n
'var: Betafite (of Hogarth 1977)'-(Ca,Na,U)2(Ti, Nb,Ta)2O6Z(OH)
'Viséite'-

List of minerals arranged by Dana 8th Edition classification

Group 1 - NATIVE ELEMENTS AND ALLOYS
Metals, other than the Platinum Group
Gold1.1.1.1Au
Silver1.1.1.2Ag
Semi-metals and non-metals
Graphite1.3.6.2C
Group 2 - SULFIDES
AmBnXp, with (m+n):p = 2:1
Acanthite2.4.1.1Ag2S
Jalpaite2.4.4.1Ag3CuS2
Stromeyerite2.4.6.1AgCuS
AmBnXp, with (m+n):p = 3:2
Bornite2.5.2.1Cu5FeS4
AmXp, with m:p = 1:1
Galena2.8.1.1PbS
Pyrrhotite2.8.10.1Fe7S8
Sphalerite2.8.2.1ZnS
AmBnXp, with (m+n):p = 1:1
Chalcopyrite2.9.1.1CuFeS2
AmBnXp, with (m+n):p = 1:2
Pyrite2.12.1.1FeS2
Group 3 - SULFOSALTS
ø > 4
Pearceite3.1.8.1[Ag9CuS4][(Ag,Cu)6(As,Sb)2S7]
3 <ø < 4
'Tetrahedrite'3.3.6.1Cu6(Cu4X2)Sb4S13
ø = 3
Proustite3.4.1.1Ag3AsS3
Pyrargyrite3.4.1.2Ag3SbS3
Group 4 - SIMPLE OXIDES
A2X3
Ilmenite4.3.5.1Fe2+TiO3
Perovskite4.3.3.1CaTiO3
AX2
Rutile4.4.1.1TiO2
var: Ilmenorutile4.4.1.2Fex(Nb,Ta)2x · 4Ti1-xO2
Group 7 - MULTIPLE OXIDES
AB2X4
Magnetite7.2.2.3Fe2+Fe3+2O4
Group 8 - MULTIPLE OXIDES CONTAINING NIOBIUM,TANTALUM OR TITANIUM
A2B2O6(O,OH,F)
'Pyrochlore Group'8.2.1.1A2Nb2(O,OH)6Z
'Pyrochlore Supergroup
var: Betafite (of Hogarth 1977)'
8.2.3.1(Ca,Na,U)2(Ti, Nb,Ta)2O6Z(OH)
AB2O6
Columbite-(Fe)8.3.2.2Fe2+Nb2O6
Fersmite8.3.3.1(Ca,Ce,Na)(Nb,Ta,Ti)2(O,OH,F)6
Nioboaeschynite-(Ce)8.3.6.2(Ce,Ca)(Nb,Ti)2(O,OH)6
Group 9 - NORMAL HALIDES
AX2
Fluorite9.2.1.1CaF2
Group 14 - ANHYDROUS NORMAL CARBONATES
A(XO3)
Calcite14.1.1.1CaCO3
Witherite14.1.3.2BaCO3
AB(XO3)2
Ankerite14.2.1.2Ca(Fe2+,Mg)(CO3)2
Barytocalcite14.2.6.1BaCa(CO3)2
Dolomite14.2.1.1CaMg(CO3)2
Miscellaneous
Burbankite14.4.4.1(Na,Ca)3(Sr,Ba,Ce)3(CO3)5
Group 16a - ANHYDROUS CARBONATES CONTAINING HYDROXYL OR HALOGEN
Bastnäsite-(Ce)16a.1.1.1Ce(CO3)F
Parisite-(Ce)16a.1.5.1CaCe2(CO3)3F2
Synchysite-(Ce)16a.1.3.1CaCe(CO3)2F
Group 28 - ANHYDROUS ACID AND NORMAL SULFATES
AXO4
Baryte28.3.1.1BaSO4
Group 38 - ANHYDROUS NORMAL PHOSPHATES, ARSENATES, AND VANADATES
AXO4
Monazite-(Ce)38.4.3.1Ce(PO4)
Group 41 - ANHYDROUS PHOSPHATES, ETC.CONTAINING HYDROXYL OR HALOGEN
A5(XO4)3Zq
Fluorapatite41.8.1.1Ca5(PO4)3F
Group 42 - HYDRATED PHOSPHATES, ETC.CONTAINING HYDROXYL OR HALOGEN
(AB)2(XO4)Zq·xH2O
Crandallite42.7.3.1CaAl3(PO4)(PO3OH)(OH)6
(AB)7(XO4)4Zq·xH2O
Turquoise42.9.3.1Cu(Al,Fe3+)6(PO4)4(OH)8 · 4H2O
Group 43 - COMPOUND PHOSPHATES, ETC.
Anhydrous Compound Phosphates, etc·, Containing Hydroxyl or Halogen
Woodhouseite43.4.1.8CaAl3(PO4)(SO4)(OH)6
Hydrated Compound Phosphates, etc·, Containing Hydroxyl or Halogen
Hotsonite43.5.18.1Al11(SO4)3(PO4)2(OH)21 · 16H2O
'Viséite'43.5.9.1
Group 51 - NESOSILICATES Insular SiO4 Groups Only
Insular SiO4 Groups Only with cations in >[6] coordination
Zircon51.5.2.1Zr(SiO4)
Group 65 - INOSILICATES Single-Width,Unbranched Chains,(W=1)
Single-Width Unbranched Chains, W=1 with chains P=2
Aegirine65.1.3c.2NaFe3+Si2O6
Diopside65.1.3a.1CaMgSi2O6
Group 71 - PHYLLOSILICATES Sheets of Six-Membered Rings
Sheets of 6-membered rings with 1:1 layers
Amesite71.1.2c.1Mg2Al(AlSiO5)(OH)4
Sheets of 6-membered rings with 2:1 layers
Muscovite71.2.2a.1KAl2(AlSi3O10)(OH)2
Group 75 - TECTOSILICATES Si Tetrahedral Frameworks
Si Tetrahedral Frameworks - SiO2 with [4] coordinated Si
Quartz75.1.3.1SiO2
Group 76 - TECTOSILICATES Al-Si Framework
Al-Si Framework with Al-Si frameworks
Albite76.1.3.1Na(AlSi3O8)
Microcline76.1.1.5K(AlSi3O8)
Unclassified Minerals, Mixtures, etc.
'Albite-Anorthite Series'-
'Alkali Feldspar'-
'Allanite Group'-{A12+REE3+}{M3+2M32+}(Si2O7)(SiO4)O(OH)
'Amphibole Supergroup'-AX2Z5((Si,Al,Ti)8O22)(OH,F,Cl,O)2
'Ancylite'-
'Bastnäsite'-
'Biotite'-K(Fe2+/Mg)2(Al/Fe3+/Mg)([Si/Al]Si2O10)(OH/F)2
'Chevkinite Group'-
'Chlorite Group'-
'Columbite-(Fe)-Columbite-(Mn) Series'-
Dolomite
var: Ferroan Dolomite
-Ca(Mg,Fe)(CO3)2
'Electrum'-(Au,Ag)
'K Feldspar'-
'Monazite'-
Muscovite
var: Sericite
-KAl2(AlSi3O10)(OH)2
'Nioboaeschynite'-
'Parisite'-
'Pyrochlore'-
'Pyrochlore Supergroup'-A2-mD2X6-wZ1-n
Rutile
var: Niobian Rutile
-(Ti,Nb)O2
Silver
var: Küstelite
-Ag
'Tetrahedrite
var: Argentian Tetrahedrite'
-(Cu,Ag)6[Cu4(Fe,Zn)2]Sb4S13

List of minerals for each chemical element

HHydrogen
H TurquoiseCu(Al,Fe3+)6(PO4)4(OH)8 · 4H2O
H BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg)([Si/Al]Si2O10)(OH/F)2
H Muscovite (var: Sericite)KAl2(AlSi3O10)(OH)2
H Fersmite(Ca,Ce,Na)(Nb,Ta,Ti)2(O,OH,F)6
H MuscoviteKAl2(AlSi3O10)(OH)2
H WoodhouseiteCaAl3(PO4)(SO4)(OH)6
H CrandalliteCaAl3(PO4)(PO3OH)(OH)6
H HotsoniteAl11(SO4)3(PO4)2(OH)21 · 16H2O
H Pyrochlore Supergroup (var: Betafite (of Hogarth 1977))(Ca,Na,U)2(Ti, Nb,Ta)2O6Z(OH)
H AmesiteMg2Al(AlSiO5)(OH)4
H Amphibole SupergroupAX2Z5((Si,Al,Ti)8O22)(OH,F,Cl,O)2
H Allanite Group{A12+REE3+}{M23+M32+}(Si2O7)(SiO4)O(OH)
H Pyrochlore GroupA2Nb2(O,OH)6Z
H Nioboaeschynite-(Ce)(Ce,Ca)(Nb,Ti)2(O,OH)6
CCarbon
C Burbankite(Na,Ca)3(Sr,Ba,Ce)3(CO3)5
C CalciteCaCO3
C Dolomite (var: Ferroan Dolomite)Ca(Mg,Fe)(CO3)2
C AnkeriteCa(Fe2+,Mg)(CO3)2
C WitheriteBaCO3
C BarytocalciteBaCa(CO3)2
C DolomiteCaMg(CO3)2
C Bastnäsite-(Ce)Ce(CO3)F
C Synchysite-(Ce)CaCe(CO3)2F
C GraphiteC
C Parisite-(Ce)CaCe2(CO3)3F2
OOxygen
O TurquoiseCu(Al,Fe3+)6(PO4)4(OH)8 · 4H2O
O Burbankite(Na,Ca)3(Sr,Ba,Ce)3(CO3)5
O FluorapatiteCa5(PO4)3F
O Rutile (var: Niobian Rutile)(Ti,Nb)O2
O CalciteCaCO3
O Dolomite (var: Ferroan Dolomite)Ca(Mg,Fe)(CO3)2
O BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg)([Si/Al]Si2O10)(OH/F)2
O AnkeriteCa(Fe2+,Mg)(CO3)2
O WitheriteBaCO3
O BaryteBaSO4
O BarytocalciteBaCa(CO3)2
O QuartzSiO2
O Muscovite (var: Sericite)KAl2(AlSi3O10)(OH)2
O MicroclineK(AlSi3O8)
O Rutile (var: Ilmenorutile)Fex(Nb,Ta)2x · 4Ti1-xO2
O Fersmite(Ca,Ce,Na)(Nb,Ta,Ti)2(O,OH,F)6
O MuscoviteKAl2(AlSi3O10)(OH)2
O AlbiteNa(AlSi3O8)
O WoodhouseiteCaAl3(PO4)(SO4)(OH)6
O CrandalliteCaAl3(PO4)(PO3OH)(OH)6
O HotsoniteAl11(SO4)3(PO4)2(OH)21 · 16H2O
O RutileTiO2
O Pyrochlore Supergroup (var: Betafite (of Hogarth 1977))(Ca,Na,U)2(Ti, Nb,Ta)2O6Z(OH)
O DolomiteCaMg(CO3)2
O AmesiteMg2Al(AlSiO5)(OH)4
O Amphibole SupergroupAX2Z5((Si,Al,Ti)8O22)(OH,F,Cl,O)2
O DiopsideCaMgSi2O6
O AegirineNaFe3+Si2O6
O Allanite Group{A12+REE3+}{M23+M32+}(Si2O7)(SiO4)O(OH)
O Columbite-(Fe)Fe2+Nb2O6
O ZirconZr(SiO4)
O MagnetiteFe2+Fe23+O4
O IlmeniteFe2+TiO3
O PerovskiteCaTiO3
O Monazite-(Ce)Ce(PO4)
O Bastnäsite-(Ce)Ce(CO3)F
O Synchysite-(Ce)CaCe(CO3)2F
O Pyrochlore GroupA2Nb2(O,OH)6Z
O Nioboaeschynite-(Ce)(Ce,Ca)(Nb,Ti)2(O,OH)6
O Parisite-(Ce)CaCe2(CO3)3F2
FFluorine
F FluorapatiteCa5(PO4)3F
F FluoriteCaF2
F BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg)([Si/Al]Si2O10)(OH/F)2
F Fersmite(Ca,Ce,Na)(Nb,Ta,Ti)2(O,OH,F)6
F Amphibole SupergroupAX2Z5((Si,Al,Ti)8O22)(OH,F,Cl,O)2
F Bastnäsite-(Ce)Ce(CO3)F
F Synchysite-(Ce)CaCe(CO3)2F
F Parisite-(Ce)CaCe2(CO3)3F2
NaSodium
Na Burbankite(Na,Ca)3(Sr,Ba,Ce)3(CO3)5
Na Fersmite(Ca,Ce,Na)(Nb,Ta,Ti)2(O,OH,F)6
Na AlbiteNa(AlSi3O8)
Na Pyrochlore Supergroup (var: Betafite (of Hogarth 1977))(Ca,Na,U)2(Ti, Nb,Ta)2O6Z(OH)
Na AegirineNaFe3+Si2O6
MgMagnesium
Mg Dolomite (var: Ferroan Dolomite)Ca(Mg,Fe)(CO3)2
Mg BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg)([Si/Al]Si2O10)(OH/F)2
Mg AnkeriteCa(Fe2+,Mg)(CO3)2
Mg DolomiteCaMg(CO3)2
Mg AmesiteMg2Al(AlSiO5)(OH)4
Mg DiopsideCaMgSi2O6
AlAluminium
Al TurquoiseCu(Al,Fe3+)6(PO4)4(OH)8 · 4H2O
Al BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg)([Si/Al]Si2O10)(OH/F)2
Al Muscovite (var: Sericite)KAl2(AlSi3O10)(OH)2
Al MicroclineK(AlSi3O8)
Al MuscoviteKAl2(AlSi3O10)(OH)2
Al AlbiteNa(AlSi3O8)
Al WoodhouseiteCaAl3(PO4)(SO4)(OH)6
Al CrandalliteCaAl3(PO4)(PO3OH)(OH)6
Al HotsoniteAl11(SO4)3(PO4)2(OH)21 · 16H2O
Al AmesiteMg2Al(AlSiO5)(OH)4
Al Amphibole SupergroupAX2Z5((Si,Al,Ti)8O22)(OH,F,Cl,O)2
SiSilicon
Si BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg)([Si/Al]Si2O10)(OH/F)2
Si QuartzSiO2
Si Muscovite (var: Sericite)KAl2(AlSi3O10)(OH)2
Si MicroclineK(AlSi3O8)
Si MuscoviteKAl2(AlSi3O10)(OH)2
Si AlbiteNa(AlSi3O8)
Si AmesiteMg2Al(AlSiO5)(OH)4
Si Amphibole SupergroupAX2Z5((Si,Al,Ti)8O22)(OH,F,Cl,O)2
Si DiopsideCaMgSi2O6
Si AegirineNaFe3+Si2O6
Si Allanite Group{A12+REE3+}{M23+M32+}(Si2O7)(SiO4)O(OH)
Si ZirconZr(SiO4)
PPhosphorus
P TurquoiseCu(Al,Fe3+)6(PO4)4(OH)8 · 4H2O
P FluorapatiteCa5(PO4)3F
P WoodhouseiteCaAl3(PO4)(SO4)(OH)6
P CrandalliteCaAl3(PO4)(PO3OH)(OH)6
P HotsoniteAl11(SO4)3(PO4)2(OH)21 · 16H2O
P Monazite-(Ce)Ce(PO4)
SSulfur
S BaryteBaSO4
S GalenaPbS
S SphaleriteZnS
S PyriteFeS2
S WoodhouseiteCaAl3(PO4)(SO4)(OH)6
S HotsoniteAl11(SO4)3(PO4)2(OH)21 · 16H2O
S ChalcopyriteCuFeS2
S AcanthiteAg2S
S JalpaiteAg3CuS2
S Tetrahedrite (var: Argentian Tetrahedrite)(Cu,Ag)6[Cu4(Fe,Zn)2]Sb4S13
S ProustiteAg3AsS3
S PyrargyriteAg3SbS3
S BorniteCu5FeS4
S StromeyeriteAgCuS
S Pearceite[Ag9CuS4][(Ag,Cu)6(As,Sb)2S7]
S TetrahedriteCu6(Cu4X2)Sb4S13
S PyrrhotiteFe7S8
ClChlorine
Cl Amphibole SupergroupAX2Z5((Si,Al,Ti)8O22)(OH,F,Cl,O)2
KPotassium
K BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg)([Si/Al]Si2O10)(OH/F)2
K Muscovite (var: Sericite)KAl2(AlSi3O10)(OH)2
K MicroclineK(AlSi3O8)
K MuscoviteKAl2(AlSi3O10)(OH)2
CaCalcium
Ca Burbankite(Na,Ca)3(Sr,Ba,Ce)3(CO3)5
Ca FluorapatiteCa5(PO4)3F
Ca FluoriteCaF2
Ca CalciteCaCO3
Ca Dolomite (var: Ferroan Dolomite)Ca(Mg,Fe)(CO3)2
Ca AnkeriteCa(Fe2+,Mg)(CO3)2
Ca BarytocalciteBaCa(CO3)2
Ca Fersmite(Ca,Ce,Na)(Nb,Ta,Ti)2(O,OH,F)6
Ca WoodhouseiteCaAl3(PO4)(SO4)(OH)6
Ca CrandalliteCaAl3(PO4)(PO3OH)(OH)6
Ca Pyrochlore Supergroup (var: Betafite (of Hogarth 1977))(Ca,Na,U)2(Ti, Nb,Ta)2O6Z(OH)
Ca DolomiteCaMg(CO3)2
Ca DiopsideCaMgSi2O6
Ca PerovskiteCaTiO3
Ca Synchysite-(Ce)CaCe(CO3)2F
Ca Nioboaeschynite-(Ce)(Ce,Ca)(Nb,Ti)2(O,OH)6
Ca Parisite-(Ce)CaCe2(CO3)3F2
TiTitanium
Ti Rutile (var: Niobian Rutile)(Ti,Nb)O2
Ti Rutile (var: Ilmenorutile)Fex(Nb,Ta)2x · 4Ti1-xO2
Ti Fersmite(Ca,Ce,Na)(Nb,Ta,Ti)2(O,OH,F)6
Ti RutileTiO2
Ti Pyrochlore Supergroup (var: Betafite (of Hogarth 1977))(Ca,Na,U)2(Ti, Nb,Ta)2O6Z(OH)
Ti Amphibole SupergroupAX2Z5((Si,Al,Ti)8O22)(OH,F,Cl,O)2
Ti IlmeniteFe2+TiO3
Ti PerovskiteCaTiO3
Ti Nioboaeschynite-(Ce)(Ce,Ca)(Nb,Ti)2(O,OH)6
FeIron
Fe TurquoiseCu(Al,Fe3+)6(PO4)4(OH)8 · 4H2O
Fe Dolomite (var: Ferroan Dolomite)Ca(Mg,Fe)(CO3)2
Fe BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg)([Si/Al]Si2O10)(OH/F)2
Fe AnkeriteCa(Fe2+,Mg)(CO3)2
Fe PyriteFeS2
Fe Rutile (var: Ilmenorutile)Fex(Nb,Ta)2x · 4Ti1-xO2
Fe ChalcopyriteCuFeS2
Fe Tetrahedrite (var: Argentian Tetrahedrite)(Cu,Ag)6[Cu4(Fe,Zn)2]Sb4S13
Fe BorniteCu5FeS4
Fe AegirineNaFe3+Si2O6
Fe PyrrhotiteFe7S8
Fe Columbite-(Fe)Fe2+Nb2O6
Fe MagnetiteFe2+Fe23+O4
Fe IlmeniteFe2+TiO3
CuCopper
Cu TurquoiseCu(Al,Fe3+)6(PO4)4(OH)8 · 4H2O
Cu ChalcopyriteCuFeS2
Cu JalpaiteAg3CuS2
Cu Tetrahedrite (var: Argentian Tetrahedrite)(Cu,Ag)6[Cu4(Fe,Zn)2]Sb4S13
Cu BorniteCu5FeS4
Cu StromeyeriteAgCuS
Cu Pearceite[Ag9CuS4][(Ag,Cu)6(As,Sb)2S7]
Cu TetrahedriteCu6(Cu4X2)Sb4S13
ZnZinc
Zn SphaleriteZnS
Zn Tetrahedrite (var: Argentian Tetrahedrite)(Cu,Ag)6[Cu4(Fe,Zn)2]Sb4S13
AsArsenic
As ProustiteAg3AsS3
As Pearceite[Ag9CuS4][(Ag,Cu)6(As,Sb)2S7]
SrStrontium
Sr Burbankite(Na,Ca)3(Sr,Ba,Ce)3(CO3)5
ZrZirconium
Zr ZirconZr(SiO4)
NbNiobium
Nb Rutile (var: Niobian Rutile)(Ti,Nb)O2
Nb Rutile (var: Ilmenorutile)Fex(Nb,Ta)2x · 4Ti1-xO2
Nb Fersmite(Ca,Ce,Na)(Nb,Ta,Ti)2(O,OH,F)6
Nb Pyrochlore Supergroup (var: Betafite (of Hogarth 1977))(Ca,Na,U)2(Ti, Nb,Ta)2O6Z(OH)
Nb Columbite-(Fe)Fe2+Nb2O6
Nb Pyrochlore GroupA2Nb2(O,OH)6Z
Nb Nioboaeschynite-(Ce)(Ce,Ca)(Nb,Ti)2(O,OH)6
AgSilver
Ag Electrum(Au,Ag)
Ag AcanthiteAg2S
Ag SilverAg
Ag JalpaiteAg3CuS2
Ag Silver (var: Küstelite)Ag
Ag Tetrahedrite (var: Argentian Tetrahedrite)(Cu,Ag)6[Cu4(Fe,Zn)2]Sb4S13
Ag ProustiteAg3AsS3
Ag PyrargyriteAg3SbS3
Ag StromeyeriteAgCuS
Ag Pearceite[Ag9CuS4][(Ag,Cu)6(As,Sb)2S7]
SbAntimony
Sb Tetrahedrite (var: Argentian Tetrahedrite)(Cu,Ag)6[Cu4(Fe,Zn)2]Sb4S13
Sb PyrargyriteAg3SbS3
Sb Pearceite[Ag9CuS4][(Ag,Cu)6(As,Sb)2S7]
Sb TetrahedriteCu6(Cu4X2)Sb4S13
BaBarium
Ba Burbankite(Na,Ca)3(Sr,Ba,Ce)3(CO3)5
Ba WitheriteBaCO3
Ba BaryteBaSO4
Ba BarytocalciteBaCa(CO3)2
CeCerium
Ce Burbankite(Na,Ca)3(Sr,Ba,Ce)3(CO3)5
Ce Fersmite(Ca,Ce,Na)(Nb,Ta,Ti)2(O,OH,F)6
Ce Monazite-(Ce)Ce(PO4)
Ce Bastnäsite-(Ce)Ce(CO3)F
Ce Synchysite-(Ce)CaCe(CO3)2F
Ce Nioboaeschynite-(Ce)(Ce,Ca)(Nb,Ti)2(O,OH)6
Ce Parisite-(Ce)CaCe2(CO3)3F2
TaTantalum
Ta Rutile (var: Ilmenorutile)Fex(Nb,Ta)2x · 4Ti1-xO2
Ta Fersmite(Ca,Ce,Na)(Nb,Ta,Ti)2(O,OH,F)6
Ta Pyrochlore Supergroup (var: Betafite (of Hogarth 1977))(Ca,Na,U)2(Ti, Nb,Ta)2O6Z(OH)
AuGold
Au Electrum(Au,Ag)
Au GoldAu
PbLead
Pb GalenaPbS
UUranium
U Pyrochlore Supergroup (var: Betafite (of Hogarth 1977))(Ca,Na,U)2(Ti, Nb,Ta)2O6Z(OH)

Geochronology

Mineralization age: Phanerozoic : 278 Ma to 147.11 ± 0.48 Ma

Important note: This table is based only on rock and mineral ages recorded on mindat.org for this locality and is not necessarily a complete representation of the geochronology, but does give an indication of possible mineralization events relevant to this locality. As more age information is added this table may expand in the future. A break in the table simply indicates a lack of data entered here, not necessarily a break in the geologic sequence. Grey background entries are from different, related, localities.

Geologic TimeRocks, Minerals and Events
Phanerozoic
 Mesozoic
  Jurassic
   Late Jurassic
ⓘ Zircon147.11 ± 0.48 MaMiaoya carbonatite, Zhushan Co., Shiyan, Hubei, China
    
  
 Paleozoic
  Permian
   Cisuralian
ⓘ Biotite278 MaMiaoya carbonatite, Zhushan Co., Shiyan, Hubei, China

Localities in this Region

Other Regions, Features and Areas that Intersect

Eurasian PlateTectonic Plate

This page contains all mineral locality references listed on mindat.org. This does not claim to be a complete list. If you know of more minerals from this site, please register so you can add to our database. This locality information is for reference purposes only. You should never attempt to visit any sites listed in mindat.org without first ensuring that you have the permission of the land and/or mineral rights holders for access and that you are aware of all safety precautions necessary.
 
Mineral and/or Locality  
Mindat.org is an outreach project of the Hudson Institute of Mineralogy, a 501(c)(3) not-for-profit organization. Public Relations by Blytheweigh.
Copyright © mindat.org and the Hudson Institute of Mineralogy 1993-2020, except where stated. Most political location boundaries are © OpenStreetMap contributors. Mindat.org relies on the contributions of thousands of members and supporters.
Privacy Policy - Terms & Conditions - Contact Us Current server date and time: March 31, 2020 11:03:20 Page generated: March 5, 2020 19:47:54
Go to top of page