Yabu City, Hyogo Prefecture, Japani
Regional Level Types | |
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Yabu City | City |
Hyogo Prefecture | Prefecture |
Japan | Country |
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Other Languages:
French:
Yabu, Hyōgo, Japon
German:
Yabu, Präfektur Hyogo, Japan
Italian:
Yabu, prefettura di Hyōgo, Giappone
Japanese:
養父市, 兵庫県, 日本
Russian:
Ябу, Хёго, Япония
Simplified Chinese:
養父市, 兵库县, 日本
Spanish:
Yabu, Prefectura de Hyōgo, Japón
Arabic:
يابو , هيوغو, اليابان
Bengali:
ইয়াবা, হিয়োগো প্রশাসনিক অঞ্চল, জাপান
Cebuano:
Yabu, Hyōgo-ken, Hapon
Classical Chinese:
養父市, 兵庫縣, 日本
Danish:
Yabu, Hyougo-præfekturet, Japan
Dutch:
Yabu, Hyogo, Japan
Estonian:
Yabu, Hyōgo prefektuur, Jaapan
Farsi/Persian:
یابو، هیوگو, استان هیوگو, ژاپن
Finnish:
Yabu, Hyōgon prefektuuri, Japani
Galician:
Yabu, Prefectura de Hyōgo, Xapón
Greek:
Γιάμπου, Χιγκόρο, Ιαπωνία
Gujarati:
યબુ, હ્યોગો પ્રીફેકચર, જાપાન
Hindi:
याबू, ह्योगो प्रीफेक्चर, जापान
Indonesian:
Yabu, Prefektur Hyogo, Jepang
Kannada:
ಯಾಬು, ಹೈಗೊ ಪ್ರಿಫೆಕ್ಚರ್, ಜಪಾನ್
Korean:
야부시, 효고현, 일본
Latvian:
Jabu, Hjogo prefektūra, Japāna
Lithuanian:
Jabu, Hiogo prefektūra, Japonija
Malay:
Yabu, Wilayah Hyōgo, Jepun
Marathi:
यबू, ह्योगो, जपान
Mazanderani:
یابو، هیوگو, جاپون
Minnan / Hokkien-Taiwanese:
Yabu-chhī, Hyôgo-koān, Ji̍t-pún
Norwegian:
Yabu, Hyōgo, Japan
Polish:
Yabu, Prefektura Hyōgo, Japonia
Portuguese:
Yabu, Hyōgo, Japão
Romanian:
Yabu, Prefectura Hyōgo, Japonia
Sinhalese:
යාබු, හයෝගෝ ප්රාන්තය, ජපානය
South Azerbaijani:
یابو، هیوقو, هیوقو اوستانی, ژاپون
Swedish:
Yabu, Hyogo prefektur, Japan
Tagalog:
Yabu, Prepektura ng Hyōgo, Hapon
Tajik (Cyrillic Script):
Ябу, Префектураи Ҳёго, Ҷопон
Tamil:
யாப்பு, ஹயோகோ ப்ரீபெக்ட்டுர், யப்பான்
Telugu:
యాబూ, హయోగో ప్రిఫెక్చర్, జపాన్
Thai:
ยาบุ, จังหวัดเฮียวโงะ, ประเทศญี่ปุ่น
Traditional Chinese:
養父, 兵庫縣, 日本
Turkish:
Yabu, Hyōgo ili, Japonya
Ukrainian:
Ябу, Префектура Хіого, Японія
Urdu:
یبو، ہیوگو, ہیوگو پریفیکچر, جاپان
Vietnamese:
Yabu, Hyōgo, Nhật Bản
Waray:
Yabu, Hyōgo, Hapon
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Rock Types Recorded
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ⓘ Acanthite Formula: Ag2S Reference: www.mineralmundi.com/japan.htm
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Alabandite Formula: MnS Reference: Fukuoka, M. (1981) Memoirs of the Faculty of Science, Kyushu University, Series D, Geology, 24, #4, 207-252. |
ⓘ Albite Formula: Na(AlSi3O8) Localities: Reference: Ohe Rikosha specimens; Masutomi museum specimens |
ⓘ Alumohydrocalcite Formula: CaAl2(CO3)2(OH)4 · 4H2O Reference: Handbook of Mineralogy |
ⓘ Annabergite Formula: Ni3(AsO4)2 · 8H2O Reference: Masutomi Museum specimens (Kyoto) |
ⓘ 'Apatite' Formula: Ca5(PO4)3(Cl/F/OH) Reference: Geology and Mineral Resources of Japan (Geological Survey of Japan, 1960)
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Arsenopyrite Formula: FeAsS Localities: Reference: Geology and Mineral Resources of Japan (Geological Survey of Japan, 1960); Kato, a., & Fujiki, Y. (1969). The Occurrence of Stannoidites from the Xenothermal Ore Deposits of the Akenobe, Ikuno, and Tada Mines, Hyogo Prefecfure, and the Fukoku Mine, Kyoto Prefecture, Japan. Mineralogical Journal, 5(6), 417-433.
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Aurichalcite Formula: (Zn,Cu)5(CO3)2(OH)6 Reference: Yamada, S. (2004) Nihonsan-koubutsu Gojuon-hairetsu Sanchi-ichiranhyou (111 pp.) |
ⓘ Baryte Formula: BaSO4 |
ⓘ Bementite Formula: Mn7Si6O15(OH)8 Reference: Fukuoka, M. (1981) Memoirs of the Faculty of Science, Kyushu University, Series D, Geology, 24, #4, 207-252. |
ⓘ Berthierite Formula: FeSb2S4 Reference: Dr. Kameki Kinoshita collection (curated at Geological Survey of Japan); Yajima, S. (1960). Metacinnabar from Sarawak and Japan, with Reference to Its Stability Relations to Cinnabar. Mineralogical Journal, 3(1), 9-18.; Harada, Zyunpéi (1954) Chemical Analyses of Japanese Minerals (III) Journal of the Faculty of Science, Hokkaido University. Series 4, Geology and mineralogy = 北海道大學理學部紀要, 8(4):289-348 |
ⓘ Bismuth Formula: Bi Localities: Reference: Ryoichi SADANAGA and Michiaki BUNNO (1974) THE WAKABAYASHI MINERAL COLLECTION Bulletin No. 7 The University Museum, The University of Tokyo |
ⓘ Bismuthinite Formula: Bi2S3 Reference: Geology and Mineral Resources of Japan (Geological Survey of Japan, 1960)
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Bornite Formula: Cu5FeS4 Reference: Geology and Mineral Resources of Japan (Geological Survey of Japan, 1960); Kato, a., & Fujiki, Y. (1969). The Occurrence of Stannoidites from the Xenothermal Ore Deposits of the Akenobe, Ikuno, and Tada Mines, Hyogo Prefecfure, and the Fukoku Mine, Kyoto Prefecture, Japan. Mineralogical Journal, 5(6), 417-433.
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Breithauptite Formula: NiSb Reference: Takeo Kato: "Two Types of Nickeliferous Pyrrhotite Deposits Found in Korea." (9 pp) |
ⓘ Breithauptite var. Arite Formula: Ni(Sb,As) Reference: Takeo Kato: "Two Types of Nickeliferous Pyrrhotite Deposits Found in Korea." (9 pp) |
ⓘ Brochantite Formula: Cu4(SO4)(OH)6 Reference: Yamada, S. (2004) Nihonsan-koubutsu Gojuon-hairetsu Sanchi-ichiranhyou (111 pp.) |
ⓘ Calcite Formula: CaCO3 Reference: Ryoichi SADANAGA and Michiaki BUNNO (1974) THE WAKABAYASHI MINERAL COLLECTION Bulletin No. 7 The University Museum, The University of Tokyo
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Cassiterite Formula: SnO2 Reference: Ryoichi SADANAGA and Michiaki BUNNO (1974) THE WAKABAYASHI MINERAL COLLECTION Bulletin No. 7 The University Museum, The University of Tokyo; Kato, a., & Fujiki, Y. (1969). The Occurrence of Stannoidites from the Xenothermal Ore Deposits of the Akenobe, Ikuno, and Tada Mines, Hyogo Prefecfure, and the Fukoku Mine, Kyoto Prefecture, Japan. Mineralogical Journal, 5(6), 417-433.
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Chalcocite Formula: Cu2S Reference: www.mineralmundi.com/japan.htm
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Chalcopyrite Formula: CuFeS2 Localities: Reference: Mining Annual Review:1985:407.; Canadian Mineralogist Vol. 25, pp,229-236 (1987); Kato, a., & Fujiki, Y. (1969). The Occurrence of Stannoidites from the Xenothermal Ore Deposits of the Akenobe, Ikuno, and Tada Mines, Hyogo Prefecfure, and the Fukoku Mine, Kyoto Prefecture, Japan. Mineralogical Journal, 5(6), 417-433.
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Chamosite Formula: (Fe2+)5Al(Si,Al)4O10(OH,O)8 Reference: Ryoichi SADANAGA and Michiaki BUNNO (1974) THE WAKABAYASHI MINERAL COLLECTION Bulletin No. 7 The University Museum, The University of Tokyo |
ⓘ 'Chlorite Group' Reference: Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Cinnabar Formula: HgS Reference: Kamitani, M., Okumura, K., Teraoka, Y., Miyano, S., and Watanabe, Y. (2007): Mineral Resources Map of East Asia. Geological Survey of Japan.; Yajima, S. (1960). Metacinnabar from Sarawak and Japan, with Reference to Its Stability Relations to Cinnabar. Mineralogical Journal, 3(1), 9-18. |
ⓘ 'Clays' Reference: Geology and Mineral Resources of Japan (Geological Survey of Japan, 1960) |
ⓘ Copper Formula: Cu Localities: Reference: Yamada, S. (2004) Nihonsan-koubutsu Gojuon-hairetsu Sanchi-ichiranhyou (111 pp.) |
ⓘ Covellite Formula: CuS Reference: Yamada, S. (2004) Nihonsan-koubutsu Gojuon-hairetsu Sanchi-ichiranhyou (111 pp.) |
ⓘ Djurleite Formula: Cu31S16 Reference: Dr. Kameki Kinoshita collection (curated at Geological Survey of Japan); Yamada, S. (2004) Nihonsan-koubutsu Gojuon-hairetsu Sanchi-ichiranhyou (111 pp.) |
ⓘ Dolomite Formula: CaMg(CO3)2 Reference: Ryoichi SADANAGA and Michiaki BUNNO (1974) THE WAKABAYASHI MINERAL COLLECTION Bulletin No. 7 The University Museum, The University of Tokyo |
ⓘ Emplectite Formula: CuBiS2 Reference: Yamada, S. (2004) Nihonsan-koubutsu Gojuon-hairetsu Sanchi-ichiranhyou (111 pp.) |
ⓘ Epidote Formula: (CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH) Localities: Reference: Dr. Kameki Kinoshita collection (curated at Geological Survey of Japan) |
ⓘ Ferberite Formula: FeWO4 Reference: Geology and Mineral Resources of Japan (Geological Survey of Japan, 1960) |
ⓘ Fluorite Formula: CaF2 Localities: Reference: Ryoichi SADANAGA and Michiaki BUNNO (1974) THE WAKABAYASHI MINERAL COLLECTION Bulletin No. 7 The University Museum, The University of Tokyo
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ 'Freibergite Subgroup' Formula: (Ag6,[Ag6]4+)(Cu4 C2+2)Sb4S12S0-1 Reference: Ryoichi SADANAGA and Michiaki BUNNO (1974) THE WAKABAYASHI MINERAL COLLECTION Bulletin No. 7 The University Museum, The University of Tokyo |
ⓘ Galena Formula: PbS Localities: Reference: Geology and Mineral Resources of Japan (Geological Survey of Japan, 1960); Canadian Mineralogist Vol. 25, pp,229-236 (1987); Kato, a., & Fujiki, Y. (1969). The Occurrence of Stannoidites from the Xenothermal Ore Deposits of the Akenobe, Ikuno, and Tada Mines, Hyogo Prefecfure, and the Fukoku Mine, Kyoto Prefecture, Japan. Mineralogical Journal, 5(6), 417-433.
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Gersdorffite Formula: NiAsS Reference: Ryoichi SADANAGA and Michiaki BUNNO (1974) THE WAKABAYASHI MINERAL COLLECTION Bulletin No. 7 The University Museum, The University of Tokyo
Shima, H., Sugaki, A., & Kitakaze, A. (1980). Study on Chemical Compositions of Nickel Minerals from Natsume Mine, Hyogo Prefecture. The Journal of the Japanese Association of Mineralogists, Petrologists and Economic Geologists, 75(Special2), 87-96. |
ⓘ Gold Formula: Au Localities: Reference: Ryoichi SADANAGA and Michiaki BUNNO (1974) THE WAKABAYASHI MINERAL COLLECTION Bulletin No. 7 The University Museum, The University of Tokyo; Yajima, S. (1960). Metacinnabar from Sarawak and Japan, with Reference to Its Stability Relations to Cinnabar. Mineralogical Journal, 3(1), 9-18. |
ⓘ Gold var. Electrum Formula: (Au,Ag) Reference: Naotatsu Shikazono & Masaaki Shimizu (1988) Electrum: Chemical composition, Mode of occurrence, and Depositional environment. Bull 32 The University Museum, The University of Tokyo |
ⓘ Hematite Formula: Fe2O3 Reference: Geology and Mineral Resources of Japan (Geological Survey of Japan, 1960)
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Ikunolite Formula: Bi4(S,Se)3 Reference: Masutomi Museum specimens (Kyoto) |
ⓘ Jadeite Formula: Na(Al,Fe3+)Si2O6 Reference: Ohe Rikosha specimens; Masutomi museum specimens |
ⓘ 'K Feldspar' Formula: KAlSi3O8 Reference: Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ 'K Feldspar var. Adularia' Formula: KAlSi3O8 Reference: Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Laitakarite Formula: Bi4Se2S Reference: (Kato, A. (1973) Sakurai Koubutsu Hyohon, 13).; Yamada, S. (2004) Nihonsan-koubutsu Gojuon-hairetsu Sanchi-ichiranhyou (111 pp.) |
ⓘ Magnesite Formula: MgCO3 |
ⓘ Magnetite Formula: Fe2+Fe3+2O4 Localities: Reference: Geology and Mineral Resources of Japan (Geological Survey of Japan, 1960)
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Mawsonite Formula: Cu6Fe2SnS8 Reference: Mining Annual Review:1985:407.; Am Min 61:3-4 pp 260-265; Canadian Mineralogist Vol. 25, pp,229-236 (1987)
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Metacinnabar Formula: HgS Reference: Yajima, S. (1960). Metacinnabar from Sarawak and Japan, with Reference to Its Stability Relations to Cinnabar. Mineralogical Journal, 3(1), 9-18. |
ⓘ Miharaite Formula: Cu4FePbBiS6 Reference: Fukuoka, M. (1981). Miharaite from the Akenobe mine and the mineral paragenesis (abstr. in Japanese). Coll. Abstr. Ann. Meet. Mineral. Soc. Japan (B-35), 107. |
ⓘ Molybdenite Formula: MoS2 Reference: Geology and Mineral Resources of Japan (Geological Survey of Japan, 1960)
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Mordenite Formula: (Na2,Ca,K2)4(Al8Si40)O96 · 28H2O Reference: Yamada, S. (2004) Nihonsan-koubutsu Gojuon-hairetsu Sanchi-ichiranhyou (111 pp.) |
ⓘ Muscovite Formula: KAl2(AlSi3O10)(OH)2 Reference: Dr. Kameki Kinoshita collection (curated at Geological Survey of Japan) |
ⓘ Muscovite var. Sericite Formula: KAl2(AlSi3O10)(OH)2 Reference: Dr. Kameki Kinoshita collection (curated at Geological Survey of Japan) |
ⓘ Nickeline Formula: NiAs Reference: Ryoichi SADANAGA and Michiaki BUNNO (1974) THE WAKABAYASHI MINERAL COLLECTION Bulletin No. 7 The University Museum, The University of Tokyo
Shima, H., Sugaki, A., & Kitakaze, A. (1980). Study on Chemical Compositions of Nickel Minerals from Natsume Mine, Hyogo Prefecture. The Journal of the Japanese Association of Mineralogists, Petrologists and Economic Geologists, 75(Special2), 87-96. |
ⓘ Nickelskutterudite Formula: (Ni,Co,Fe)As3 Reference: Matsubara & Miyawaki (2006) Catalogue of Japanese Minerals. (National Science Museum, Tokyo) |
ⓘ Orthoclase Formula: K(AlSi3O8) Reference: www.mineralmundi.com/japan.htm |
ⓘ Paragonite Formula: NaAl2(AlSi3O10)(OH)2 Reference: Ohe Rikosha specimens; Masutomi museum specimens |
ⓘ Pavonite Formula: AgBi3S5 Reference: Yamada, S. (2004) Nihonsan-koubutsu Gojuon-hairetsu Sanchi-ichiranhyou (111 pp.) |
ⓘ Pentlandite Formula: (NixFey)Σ9S8 Reference: Takeo Kato: "Two Types of Nickeliferous Pyrrhotite Deposits Found in Korea." (9 pp); Yamada, S. (2004) Nihonsan-koubutsu Gojuon-hairetsu Sanchi-ichiranhyou (111 pp.) |
ⓘ Polybasite Formula: [Ag6Sb2S7][Ag9CuS4] Reference: www.mineralmundi.com/japan.htm
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Pyrite Formula: FeS2 Localities: Reference: Ryoichi SADANAGA and Michiaki BUNNO (1974) THE WAKABAYASHI MINERAL COLLECTION Bulletin No. 7 The University Museum, The University of Tokyo |
ⓘ Pyroxmangite Formula: Mn2+SiO3 Reference: Fukuoka, M. (1981) Memoirs of the Faculty of Science, Kyushu University, Series D, Geology, 24, #4, 207-252. |
ⓘ Pyrrhotite Formula: Fe1-xS Localities: Reference: Ryoichi SADANAGA and Michiaki BUNNO (1974) THE WAKABAYASHI MINERAL COLLECTION Bulletin No. 7 The University Museum, The University of Tokyo |
ⓘ Quartz Formula: SiO2 Localities: Reference: Ryoichi SADANAGA and Michiaki BUNNO (1974) THE WAKABAYASHI MINERAL COLLECTION Bulletin No. 7 The University Museum, The University of Tokyo; Naotatsu Shikazono & Masaaki Shimizu (1988) Electrum: Chemical composition, Mode of occurrence, and Depositional environment. Bull 32 The University Museum, The University of Tokyo; Yajima, S. (1960). Metacinnabar from Sarawak and Japan, with Reference to Its Stability Relations to Cinnabar. Mineralogical Journal, 3(1), 9-18. |
ⓘ Quartz var. Chalcedony Formula: SiO2 |
ⓘ Quartz var. Milky Quartz Formula: SiO2 Reference: Takeo Katou (1917) journal of the Geological Society of Tokyo, 24, #287, 35-39. |
ⓘ Rammelsbergite Formula: NiAs2 Reference: Matsukuma (1958) Kouzan Chishitsu, 8, 55. |
ⓘ Rhodochrosite Formula: MnCO3 Localities: Reference: Fukuoka, M. (1981) Memoirs of the Faculty of Science, Kyushu University, Series D, Geology, 24, #4, 207-252. |
ⓘ Rhodonite Formula: CaMn3Mn[Si5O15] Localities: Reference: Fukuoka, M. (1981) Memoirs of the Faculty of Science, Kyushu University, Series D, Geology, 24, #4, 207-252. |
ⓘ Roquesite Formula: CuInS2 Reference: Mineralogical Journal 5 (1968) 276-284; Mining Annual Review:1985:407.; Mineralogical Journal Vol. 12 (1984) , No. 4 pp 162-172; Canadian Mineralogist Vol. 25, pp,229-236 (1987); Kato, a., & Fujiki, Y. (1969). The Occurrence of Stannoidites from the Xenothermal Ore Deposits of the Akenobe, Ikuno, and Tada Mines, Hyogo Prefecfure, and the Fukoku Mine, Kyoto Prefecture, Japan. Mineralogical Journal, 5(6), 417-433.
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Saponite Formula: Ca0.25(Mg,Fe)3((Si,Al)4O10)(OH)2 · nH2O Reference: Dr. Kameki Kinoshita collection (curated at Geological Survey of Japan) |
ⓘ Scheelite Formula: Ca(WO4) Reference: Ryoichi SADANAGA and Michiaki BUNNO (1974) THE WAKABAYASHI MINERAL COLLECTION Bulletin No. 7 The University Museum, The University of Tokyo; Kato, a., & Fujiki, Y. (1969). The Occurrence of Stannoidites from the Xenothermal Ore Deposits of the Akenobe, Ikuno, and Tada Mines, Hyogo Prefecfure, and the Fukoku Mine, Kyoto Prefecture, Japan. Mineralogical Journal, 5(6), 417-433.
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Senandorite Formula: AgPbSb3S6 Reference: Ito, T., Muraoka, H. (1960) Zeitschrift für Kristallographie, 113, 94-98. |
ⓘ Senandorite var. Nakaseite Formula: CuAg3Pb4Sb12S24 Reference: Ito, T., Muraoka, H. (1960) Zeitschrift für Kristallographie, 113, 94-98. |
ⓘ 'Serpentine Subgroup' Formula: D3[Si2O5](OH)4 Localities: Reference: Rocks & Min.: 22:112. |
ⓘ Siderite Formula: FeCO3 Reference: Ryoichi SADANAGA and Michiaki BUNNO (1974) THE WAKABAYASHI MINERAL COLLECTION Bulletin No. 7 The University Museum, The University of Tokyo; Kato, a., & Fujiki, Y. (1969). The Occurrence of Stannoidites from the Xenothermal Ore Deposits of the Akenobe, Ikuno, and Tada Mines, Hyogo Prefecfure, and the Fukoku Mine, Kyoto Prefecture, Japan. Mineralogical Journal, 5(6), 417-433. |
ⓘ Silver Formula: Ag Reference: Yamada, S. (2004) Nihonsan-koubutsu Gojuon-hairetsu Sanchi-ichiranhyou (111 pp.)
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Spessartine Formula: Mn2+3Al2(SiO4)3 Reference: Fukuoka, M. (1981) Memoirs of the Faculty of Science, Kyushu University, Series D, Geology, 24, #4, 207-252. |
ⓘ Sphalerite Formula: ZnS Localities: Reference: Ryoichi SADANAGA and Michiaki BUNNO (1974) THE WAKABAYASHI MINERAL COLLECTION Bulletin No. 7 The University Museum, The University of Tokyo |
ⓘ Sphalerite var. Marmatite Formula: (Zn,Fe)S Reference: Yamada, S. (2004) Nihonsan-koubutsu Gojuon-hairetsu Sanchi-ichiranhyou (111 pp.)
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Stannite Formula: Cu2FeSnS4 Reference: Dr. Matsuo Nambu collection (curated at Geological Survey of Japan); Shimizu, M., Shimizu, M., & Tsunoda, K. (2008). Physicochemical Environment of Formation of Tin Sulfide-Bearing. Far Eastern Studies 7:23-40
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Stannoidite Formula: Cu+6Cu2+2(Fe2+,Zn)3Sn2S12 Reference: Am Min 61:3-4 pp 260-265; Canadian Mineralogist Vol. 25, pp,229-236 (1987); Kato, a., & Fujiki, Y. (1969). The Occurrence of Stannoidites from the Xenothermal Ore Deposits of the Akenobe, Ikuno, and Tada Mines, Hyogo Prefecfure, and the Fukoku Mine, Kyoto Prefecture, Japan. Mineralogical Journal, 5(6), 417-433.
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Stephanite Formula: Ag5SbS4 Reference: Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ 'Stibiconite' Formula: Sb3+Sb5+2O6(OH) Reference: Hiroaki Tano specimen |
ⓘ Stibnite Formula: Sb2S3 Reference: Ryoichi SADANAGA and Michiaki BUNNO (1974) THE WAKABAYASHI MINERAL COLLECTION Bulletin No. 7 The University Museum, The University of Tokyo; Naotatsu Shikazono & Masaaki Shimizu (1988) Electrum: Chemical composition, Mode of occurrence, and Depositional environment. Bull 32 The University Museum, The University of Tokyo |
ⓘ 'Tennantite Subgroup' Formula: Cu6(Cu4C2+2)As4S12S Reference: Canadian Mineralogist Vol. 25, pp,229-236 (1987)
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Tephroite Formula: Mn2+2SiO4 Reference: Fukuoka, M. (1981) Memoirs of the Faculty of Science, Kyushu University, Series D, Geology, 24, #4, 207-252. |
ⓘ 'Tetrahedrite Subgroup' Formula: Cu6(Cu4C2+2)Sb4S12S Localities: Reference: Dr. Kameki Kinoshita collection (curated at Geological Survey of Japan) |
ⓘ Topaz Formula: Al2(SiO4)(F,OH)2 Reference: www.mineralmundi.com/japan.htm
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Ullmannite Formula: NiSbS Localities: Reference: Dr. Kameki Kinoshita collection (curated at Geological Survey of Japan) |
ⓘ Vauquelinite Formula: Pb2Cu(CrO4)(PO4)(OH) Reference: http://staff.aist.go.jp/miyagi.iso14000/Works/Review/coop/0028/874.html (Dr. Takashi Yamada lecture to the Mineralogical Society) |
ⓘ 'Wolframite Group' Reference: Kato, a., & Fujiki, Y. (1969). The Occurrence of Stannoidites from the Xenothermal Ore Deposits of the Akenobe, Ikuno, and Tada Mines, Hyogo Prefecfure, and the Fukoku Mine, Kyoto Prefecture, Japan. Mineralogical Journal, 5(6), 417-433.
Imai, H., Lee, M. S., Iida, K., Fujiki, Y., & Takenouchi, S. (1975). Geologic structure and mineralization of the xenothermal vein-type deposits in Japan. Economic Geology, 70(4), 647-676. |
ⓘ Xonotlite Formula: Ca6(Si6O17)(OH)2 Reference: Yamada, S. (2004) Nihonsan-koubutsu Gojuon-hairetsu Sanchi-ichiranhyou (111 pp.) |
Gallery:
List of minerals arranged by Strunz 10th Edition classification
Group 1 - Elements | |||
---|---|---|---|
ⓘ | Bismuth | 1.CA.05 | Bi |
ⓘ | Copper | 1.AA.05 | Cu |
ⓘ | Gold | 1.AA.05 | Au |
ⓘ | var. Electrum | 1.AA.05 | (Au,Ag) |
ⓘ | Silver | 1.AA.05 | Ag |
Group 2 - Sulphides and Sulfosalts | |||
ⓘ | Acanthite | 2.BA.35 | Ag2S |
ⓘ | Alabandite | 2.CD.10 | MnS |
ⓘ | Arsenopyrite | 2.EB.20 | FeAsS |
ⓘ | Berthierite | 2.HA.20 | FeSb2S4 |
ⓘ | Bismuthinite | 2.DB.05 | Bi2S3 |
ⓘ | Bornite | 2.BA.15 | Cu5FeS4 |
ⓘ | Breithauptite | 2.CC.05 | NiSb |
ⓘ | var. Arite | 2.CC.05 | Ni(Sb,As) |
ⓘ | Chalcocite | 2.BA.05 | Cu2S |
ⓘ | Chalcopyrite | 2.CB.10a | CuFeS2 |
ⓘ | Cinnabar | 2.CD.15a | HgS |
ⓘ | Covellite | 2.CA.05a | CuS |
ⓘ | Djurleite | 2.BA.05 | Cu31S16 |
ⓘ | Emplectite | 2.HA.05 | CuBiS2 |
ⓘ | 'Freibergite Subgroup' | 2.GB.05 | (Ag6,[Ag6]4+)(Cu4 C2+2)Sb4S12S0-1 |
ⓘ | Galena | 2.CD.10 | PbS |
ⓘ | Gersdorffite | 2.EB.25 | NiAsS |
ⓘ | Ikunolite | 2.DC.05 | Bi4(S,Se)3 |
ⓘ | Laitakarite | 2.DC.05 | Bi4Se2S |
ⓘ | Mawsonite | 2.CB.20 | Cu6Fe2SnS8 |
ⓘ | Metacinnabar | 2.CB.05a | HgS |
ⓘ | Miharaite | 2.LB.05 | Cu4FePbBiS6 |
ⓘ | Molybdenite | 2.EA.30 | MoS2 |
ⓘ | Nickeline | 2.CC.05 | NiAs |
ⓘ | Nickelskutterudite | 2.EC.05 | (Ni,Co,Fe)As3 |
ⓘ | Pavonite | 2.JA.05a | AgBi3S5 |
ⓘ | Pentlandite | 2.BB.15 | (NixFey)Σ9S8 |
ⓘ | Polybasite | 2.GB.15 | [Ag6Sb2S7][Ag9CuS4] |
ⓘ | Pyrite | 2.EB.05a | FeS2 |
ⓘ | Pyrrhotite | 2.CC.10 | Fe1-xS |
ⓘ | Rammelsbergite | 2.EB.15a | NiAs2 |
ⓘ | Roquesite | 2.CB.10a | CuInS2 |
ⓘ | Senandorite | 2.JB. | AgPbSb3S6 |
ⓘ | var. Nakaseite | 2.JB. | CuAg3Pb4Sb12S24 |
ⓘ | Sphalerite | 2.CB.05a | ZnS |
ⓘ | var. Marmatite | 2.CB.05a | (Zn,Fe)S |
ⓘ | Stannite | 2.CB.15a | Cu2FeSnS4 |
ⓘ | Stannoidite | 2.CB.15c | Cu+6Cu2+2(Fe2+,Zn)3Sn2S12 |
ⓘ | Stephanite | 2.GB.10 | Ag5SbS4 |
ⓘ | Stibnite | 2.DB.05 | Sb2S3 |
ⓘ | 'Tennantite Subgroup' | 2.GB.05 | Cu6(Cu4C2+2)As4S12S |
ⓘ | 'Tetrahedrite Subgroup' | 2.GB.05 | Cu6(Cu4C2+2)Sb4S12S |
ⓘ | Ullmannite | 2.EB.25 | NiSbS |
Group 3 - Halides | |||
ⓘ | Fluorite | 3.AB.25 | CaF2 |
Group 4 - Oxides and Hydroxides | |||
ⓘ | Cassiterite | 4.DB.05 | SnO2 |
ⓘ | Ferberite | 4.DB.30 | FeWO4 |
ⓘ | Hematite | 4.CB.05 | Fe2O3 |
ⓘ | Magnetite | 4.BB.05 | Fe2+Fe3+2O4 |
ⓘ | Quartz | 4.DA.05 | SiO2 |
ⓘ | var. Chalcedony | 4.DA.05 | SiO2 |
ⓘ | var. Milky Quartz | 4.DA.05 | SiO2 |
ⓘ | 'Stibiconite' | 4.DH.20 | Sb3+Sb5+2O6(OH) |
ⓘ | 'Wolframite Group' | 4.DB.30 va | |
Group 5 - Nitrates and Carbonates | |||
ⓘ | Alumohydrocalcite | 5.DB.05 | CaAl2(CO3)2(OH)4 · 4H2O |
ⓘ | Aurichalcite | 5.BA.15 | (Zn,Cu)5(CO3)2(OH)6 |
ⓘ | Calcite | 5.AB.05 | CaCO3 |
ⓘ | Dolomite | 5.AB.10 | CaMg(CO3)2 |
ⓘ | Magnesite | 5.AB.05 | MgCO3 |
ⓘ | Rhodochrosite | 5.AB.05 | MnCO3 |
ⓘ | Siderite | 5.AB.05 | FeCO3 |
Group 7 - Sulphates, Chromates, Molybdates and Tungstates | |||
ⓘ | Baryte | 7.AD.35 | BaSO4 |
ⓘ | Brochantite | 7.BB.25 | Cu4(SO4)(OH)6 |
ⓘ | Scheelite | 7.GA.05 | Ca(WO4) |
ⓘ | Vauquelinite | 7.FC.05 | Pb2Cu(CrO4)(PO4)(OH) |
Group 8 - Phosphates, Arsenates and Vanadates | |||
ⓘ | Annabergite | 8.CE.40 | Ni3(AsO4)2 · 8H2O |
Group 9 - Silicates | |||
ⓘ | Albite | 9.FA.35 | Na(AlSi3O8) |
ⓘ | Bementite | 9.EE.05 | Mn7Si6O15(OH)8 |
ⓘ | Chamosite | 9.EC.55 | (Fe2+)5Al(Si,Al)4O10(OH,O)8 |
ⓘ | Epidote | 9.BG.05a | (CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH) |
ⓘ | Jadeite | 9.DA.25 | Na(Al,Fe3+)Si2O6 |
ⓘ | Mordenite | 9.GD.35 | (Na2,Ca,K2)4(Al8Si40)O96 · 28H2O |
ⓘ | Muscovite | 9.EC.15 | KAl2(AlSi3O10)(OH)2 |
ⓘ | var. Sericite | 9.EC.15 | KAl2(AlSi3O10)(OH)2 |
ⓘ | Orthoclase | 9.FA.30 | K(AlSi3O8) |
ⓘ | Paragonite | 9.EC.15 | NaAl2(AlSi3O10)(OH)2 |
ⓘ | Pyroxmangite | 9.DO.05 | Mn2+SiO3 |
ⓘ | Rhodonite | 9.DK.05 | CaMn3Mn[Si5O15] |
ⓘ | Saponite | 9.EC.45 | Ca0.25(Mg,Fe)3((Si,Al)4O10)(OH)2 · nH2O |
ⓘ | Spessartine | 9.AD.25 | Mn2+3Al2(SiO4)3 |
ⓘ | Tephroite | 9.AC.05 | Mn2+2SiO4 |
ⓘ | Topaz | 9.AF.35 | Al2(SiO4)(F,OH)2 |
ⓘ | Xonotlite | 9.DG.35 | Ca6(Si6O17)(OH)2 |
Unclassified Minerals, Rocks, etc. | |||
ⓘ | 'Apatite' | - | Ca5(PO4)3(Cl/F/OH) |
ⓘ | 'Chlorite Group' | - | |
ⓘ | 'Clays' | - | |
ⓘ | 'K Feldspar' | - | KAlSi3O8 |
ⓘ | 'var. Adularia' | - | KAlSi3O8 |
ⓘ | 'Serpentine Subgroup' | - | D3[Si2O5](OH)4 |
List of minerals for each chemical element
H | Hydrogen | |
---|---|---|
H | ⓘ Serpentine Subgroup | D3[Si2O5](OH)4 |
H | ⓘ Chamosite | (Fe2+)5Al(Si,Al)4O10(OH,O)8 |
H | ⓘ Vauquelinite | Pb2Cu(CrO4)(PO4)(OH) |
H | ⓘ Apatite | Ca5(PO4)3(Cl/F/OH) |
H | ⓘ Topaz | Al2(SiO4)(F,OH)2 |
H | ⓘ Annabergite | Ni3(AsO4)2 · 8H2O |
H | ⓘ Muscovite var. Sericite | KAl2(AlSi3O10)(OH)2 |
H | ⓘ Bementite | Mn7Si6O15(OH)8 |
H | ⓘ Saponite | Ca0.25(Mg,Fe)3((Si,Al)4O10)(OH)2 · nH2O |
H | ⓘ Epidote | (CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH) |
H | ⓘ Stibiconite | Sb3+Sb25+O6(OH) |
H | ⓘ Paragonite | NaAl2(AlSi3O10)(OH)2 |
H | ⓘ Mordenite | (Na2,Ca,K2)4(Al8Si40)O96 · 28H2O |
H | ⓘ Brochantite | Cu4(SO4)(OH)6 |
H | ⓘ Aurichalcite | (Zn,Cu)5(CO3)2(OH)6 |
H | ⓘ Xonotlite | Ca6(Si6O17)(OH)2 |
H | ⓘ Alumohydrocalcite | CaAl2(CO3)2(OH)4 · 4H2O |
H | ⓘ Muscovite | KAl2(AlSi3O10)(OH)2 |
C | Carbon | |
C | ⓘ Dolomite | CaMg(CO3)2 |
C | ⓘ Magnesite | MgCO3 |
C | ⓘ Calcite | CaCO3 |
C | ⓘ Siderite | FeCO3 |
C | ⓘ Rhodochrosite | MnCO3 |
C | ⓘ Aurichalcite | (Zn,Cu)5(CO3)2(OH)6 |
C | ⓘ Alumohydrocalcite | CaAl2(CO3)2(OH)4 · 4H2O |
O | Oxygen | |
O | ⓘ Quartz | SiO2 |
O | ⓘ Dolomite | CaMg(CO3)2 |
O | ⓘ Magnesite | MgCO3 |
O | ⓘ Baryte | BaSO4 |
O | ⓘ Quartz var. Chalcedony | SiO2 |
O | ⓘ Serpentine Subgroup | D3[Si2O5](OH)4 |
O | ⓘ Calcite | CaCO3 |
O | ⓘ Scheelite | Ca(WO4) |
O | ⓘ Cassiterite | SnO2 |
O | ⓘ Siderite | FeCO3 |
O | ⓘ Chamosite | (Fe2+)5Al(Si,Al)4O10(OH,O)8 |
O | ⓘ Vauquelinite | Pb2Cu(CrO4)(PO4)(OH) |
O | ⓘ Ferberite | FeWO4 |
O | ⓘ Magnetite | Fe2+Fe23+O4 |
O | ⓘ Hematite | Fe2O3 |
O | ⓘ Apatite | Ca5(PO4)3(Cl/F/OH) |
O | ⓘ Orthoclase | K(AlSi3O8) |
O | ⓘ Topaz | Al2(SiO4)(F,OH)2 |
O | ⓘ Annabergite | Ni3(AsO4)2 · 8H2O |
O | ⓘ Muscovite var. Sericite | KAl2(AlSi3O10)(OH)2 |
O | ⓘ Rhodonite | CaMn3Mn[Si5O15] |
O | ⓘ Tephroite | Mn22+SiO4 |
O | ⓘ Spessartine | Mn32+Al2(SiO4)3 |
O | ⓘ Bementite | Mn7Si6O15(OH)8 |
O | ⓘ Rhodochrosite | MnCO3 |
O | ⓘ Pyroxmangite | Mn2+SiO3 |
O | ⓘ Saponite | Ca0.25(Mg,Fe)3((Si,Al)4O10)(OH)2 · nH2O |
O | ⓘ Epidote | (CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH) |
O | ⓘ Quartz var. Milky Quartz | SiO2 |
O | ⓘ Stibiconite | Sb3+Sb25+O6(OH) |
O | ⓘ Jadeite | Na(Al,Fe3+)Si2O6 |
O | ⓘ Paragonite | NaAl2(AlSi3O10)(OH)2 |
O | ⓘ Albite | Na(AlSi3O8) |
O | ⓘ Mordenite | (Na2,Ca,K2)4(Al8Si40)O96 · 28H2O |
O | ⓘ Brochantite | Cu4(SO4)(OH)6 |
O | ⓘ Aurichalcite | (Zn,Cu)5(CO3)2(OH)6 |
O | ⓘ Xonotlite | Ca6(Si6O17)(OH)2 |
O | ⓘ Alumohydrocalcite | CaAl2(CO3)2(OH)4 · 4H2O |
O | ⓘ Muscovite | KAl2(AlSi3O10)(OH)2 |
O | ⓘ K Feldspar var. Adularia | KAlSi3O8 |
O | ⓘ K Feldspar | KAlSi3O8 |
F | Fluorine | |
F | ⓘ Fluorite | CaF2 |
F | ⓘ Apatite | Ca5(PO4)3(Cl/F/OH) |
F | ⓘ Topaz | Al2(SiO4)(F,OH)2 |
Na | Sodium | |
Na | ⓘ Jadeite | Na(Al,Fe3+)Si2O6 |
Na | ⓘ Paragonite | NaAl2(AlSi3O10)(OH)2 |
Na | ⓘ Albite | Na(AlSi3O8) |
Na | ⓘ Mordenite | (Na2,Ca,K2)4(Al8Si40)O96 · 28H2O |
Mg | Magnesium | |
Mg | ⓘ Dolomite | CaMg(CO3)2 |
Mg | ⓘ Magnesite | MgCO3 |
Mg | ⓘ Saponite | Ca0.25(Mg,Fe)3((Si,Al)4O10)(OH)2 · nH2O |
Al | Aluminium | |
Al | ⓘ Chamosite | (Fe2+)5Al(Si,Al)4O10(OH,O)8 |
Al | ⓘ Orthoclase | K(AlSi3O8) |
Al | ⓘ Topaz | Al2(SiO4)(F,OH)2 |
Al | ⓘ Muscovite var. Sericite | KAl2(AlSi3O10)(OH)2 |
Al | ⓘ Spessartine | Mn32+Al2(SiO4)3 |
Al | ⓘ Saponite | Ca0.25(Mg,Fe)3((Si,Al)4O10)(OH)2 · nH2O |
Al | ⓘ Epidote | (CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH) |
Al | ⓘ Jadeite | Na(Al,Fe3+)Si2O6 |
Al | ⓘ Paragonite | NaAl2(AlSi3O10)(OH)2 |
Al | ⓘ Albite | Na(AlSi3O8) |
Al | ⓘ Mordenite | (Na2,Ca,K2)4(Al8Si40)O96 · 28H2O |
Al | ⓘ Alumohydrocalcite | CaAl2(CO3)2(OH)4 · 4H2O |
Al | ⓘ Muscovite | KAl2(AlSi3O10)(OH)2 |
Al | ⓘ K Feldspar var. Adularia | KAlSi3O8 |
Al | ⓘ K Feldspar | KAlSi3O8 |
Si | Silicon | |
Si | ⓘ Quartz | SiO2 |
Si | ⓘ Quartz var. Chalcedony | SiO2 |
Si | ⓘ Serpentine Subgroup | D3[Si2O5](OH)4 |
Si | ⓘ Chamosite | (Fe2+)5Al(Si,Al)4O10(OH,O)8 |
Si | ⓘ Orthoclase | K(AlSi3O8) |
Si | ⓘ Topaz | Al2(SiO4)(F,OH)2 |
Si | ⓘ Muscovite var. Sericite | KAl2(AlSi3O10)(OH)2 |
Si | ⓘ Rhodonite | CaMn3Mn[Si5O15] |
Si | ⓘ Tephroite | Mn22+SiO4 |
Si | ⓘ Spessartine | Mn32+Al2(SiO4)3 |
Si | ⓘ Bementite | Mn7Si6O15(OH)8 |
Si | ⓘ Pyroxmangite | Mn2+SiO3 |
Si | ⓘ Saponite | Ca0.25(Mg,Fe)3((Si,Al)4O10)(OH)2 · nH2O |
Si | ⓘ Epidote | (CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH) |
Si | ⓘ Quartz var. Milky Quartz | SiO2 |
Si | ⓘ Jadeite | Na(Al,Fe3+)Si2O6 |
Si | ⓘ Paragonite | NaAl2(AlSi3O10)(OH)2 |
Si | ⓘ Albite | Na(AlSi3O8) |
Si | ⓘ Mordenite | (Na2,Ca,K2)4(Al8Si40)O96 · 28H2O |
Si | ⓘ Xonotlite | Ca6(Si6O17)(OH)2 |
Si | ⓘ Muscovite | KAl2(AlSi3O10)(OH)2 |
Si | ⓘ K Feldspar var. Adularia | KAlSi3O8 |
Si | ⓘ K Feldspar | KAlSi3O8 |
P | Phosphorus | |
P | ⓘ Vauquelinite | Pb2Cu(CrO4)(PO4)(OH) |
P | ⓘ Apatite | Ca5(PO4)3(Cl/F/OH) |
S | Sulfur | |
S | ⓘ Roquesite | CuInS2 |
S | ⓘ Chalcopyrite | CuFeS2 |
S | ⓘ Mawsonite | Cu6Fe2SnS8 |
S | ⓘ Senandorite var. Nakaseite | CuAg3Pb4Sb12S24 |
S | ⓘ Tetrahedrite Subgroup | Cu6(Cu4C22+)Sb4S12S |
S | ⓘ Stibnite | Sb2S3 |
S | ⓘ Berthierite | FeSb2S4 |
S | ⓘ Baryte | BaSO4 |
S | ⓘ Sphalerite | ZnS |
S | ⓘ Pyrite | FeS2 |
S | ⓘ Freibergite Subgroup | (Ag6,[Ag6]4+)(Cu4 C22+)Sb4S12S0-1 |
S | ⓘ Bornite | Cu5FeS4 |
S | ⓘ Stannoidite | Cu6+Cu22+(Fe2+,Zn)3Sn2S12 |
S | ⓘ Gersdorffite | NiAsS |
S | ⓘ Pyrrhotite | Fe1-xS |
S | ⓘ Galena | PbS |
S | ⓘ Arsenopyrite | FeAsS |
S | ⓘ Bismuthinite | Bi2S3 |
S | ⓘ Molybdenite | MoS2 |
S | ⓘ Polybasite | [Ag6Sb2S7][Ag9CuS4] |
S | ⓘ Acanthite | Ag2S |
S | ⓘ Chalcocite | Cu2S |
S | ⓘ Ikunolite | Bi4(S,Se)3 |
S | ⓘ Alabandite | MnS |
S | ⓘ Djurleite | Cu31S16 |
S | ⓘ Ullmannite | NiSbS |
S | ⓘ Tennantite Subgroup | Cu6(Cu4C22+)As4S12S |
S | ⓘ Pentlandite | (NixFey)Σ9S8 |
S | ⓘ Cinnabar | HgS |
S | ⓘ Stannite | Cu2FeSnS4 |
S | ⓘ Laitakarite | Bi4Se2S |
S | ⓘ Metacinnabar | HgS |
S | ⓘ Covellite | CuS |
S | ⓘ Brochantite | Cu4(SO4)(OH)6 |
S | ⓘ Sphalerite var. Marmatite | (Zn,Fe)S |
S | ⓘ Emplectite | CuBiS2 |
S | ⓘ Pavonite | AgBi3S5 |
S | ⓘ Senandorite | AgPbSb3S6 |
S | ⓘ Miharaite | Cu4FePbBiS6 |
S | ⓘ Stephanite | Ag5SbS4 |
Cl | Chlorine | |
Cl | ⓘ Apatite | Ca5(PO4)3(Cl/F/OH) |
K | Potassium | |
K | ⓘ Orthoclase | K(AlSi3O8) |
K | ⓘ Muscovite var. Sericite | KAl2(AlSi3O10)(OH)2 |
K | ⓘ Mordenite | (Na2,Ca,K2)4(Al8Si40)O96 · 28H2O |
K | ⓘ Muscovite | KAl2(AlSi3O10)(OH)2 |
K | ⓘ K Feldspar var. Adularia | KAlSi3O8 |
K | ⓘ K Feldspar | KAlSi3O8 |
Ca | Calcium | |
Ca | ⓘ Dolomite | CaMg(CO3)2 |
Ca | ⓘ Calcite | CaCO3 |
Ca | ⓘ Fluorite | CaF2 |
Ca | ⓘ Scheelite | Ca(WO4) |
Ca | ⓘ Apatite | Ca5(PO4)3(Cl/F/OH) |
Ca | ⓘ Rhodonite | CaMn3Mn[Si5O15] |
Ca | ⓘ Saponite | Ca0.25(Mg,Fe)3((Si,Al)4O10)(OH)2 · nH2O |
Ca | ⓘ Epidote | (CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH) |
Ca | ⓘ Mordenite | (Na2,Ca,K2)4(Al8Si40)O96 · 28H2O |
Ca | ⓘ Xonotlite | Ca6(Si6O17)(OH)2 |
Ca | ⓘ Alumohydrocalcite | CaAl2(CO3)2(OH)4 · 4H2O |
Cr | Chromium | |
Cr | ⓘ Vauquelinite | Pb2Cu(CrO4)(PO4)(OH) |
Mn | Manganese | |
Mn | ⓘ Alabandite | MnS |
Mn | ⓘ Rhodonite | CaMn3Mn[Si5O15] |
Mn | ⓘ Tephroite | Mn22+SiO4 |
Mn | ⓘ Spessartine | Mn32+Al2(SiO4)3 |
Mn | ⓘ Bementite | Mn7Si6O15(OH)8 |
Mn | ⓘ Rhodochrosite | MnCO3 |
Mn | ⓘ Pyroxmangite | Mn2+SiO3 |
Fe | Iron | |
Fe | ⓘ Chalcopyrite | CuFeS2 |
Fe | ⓘ Mawsonite | Cu6Fe2SnS8 |
Fe | ⓘ Berthierite | FeSb2S4 |
Fe | ⓘ Pyrite | FeS2 |
Fe | ⓘ Bornite | Cu5FeS4 |
Fe | ⓘ Stannoidite | Cu6+Cu22+(Fe2+,Zn)3Sn2S12 |
Fe | ⓘ Pyrrhotite | Fe1-xS |
Fe | ⓘ Siderite | FeCO3 |
Fe | ⓘ Chamosite | (Fe2+)5Al(Si,Al)4O10(OH,O)8 |
Fe | ⓘ Ferberite | FeWO4 |
Fe | ⓘ Magnetite | Fe2+Fe23+O4 |
Fe | ⓘ Arsenopyrite | FeAsS |
Fe | ⓘ Hematite | Fe2O3 |
Fe | ⓘ Nickelskutterudite | (Ni,Co,Fe)As3 |
Fe | ⓘ Saponite | Ca0.25(Mg,Fe)3((Si,Al)4O10)(OH)2 · nH2O |
Fe | ⓘ Epidote | (CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH) |
Fe | ⓘ Pentlandite | (NixFey)Σ9S8 |
Fe | ⓘ Stannite | Cu2FeSnS4 |
Fe | ⓘ Jadeite | Na(Al,Fe3+)Si2O6 |
Fe | ⓘ Sphalerite var. Marmatite | (Zn,Fe)S |
Fe | ⓘ Miharaite | Cu4FePbBiS6 |
Co | Cobalt | |
Co | ⓘ Nickelskutterudite | (Ni,Co,Fe)As3 |
Ni | Nickel | |
Ni | ⓘ Nickeline | NiAs |
Ni | ⓘ Gersdorffite | NiAsS |
Ni | ⓘ Nickelskutterudite | (Ni,Co,Fe)As3 |
Ni | ⓘ Annabergite | Ni3(AsO4)2 · 8H2O |
Ni | ⓘ Ullmannite | NiSbS |
Ni | ⓘ Rammelsbergite | NiAs2 |
Ni | ⓘ Breithauptite | NiSb |
Ni | ⓘ Breithauptite var. Arite | Ni(Sb,As) |
Ni | ⓘ Pentlandite | (NixFey)Σ9S8 |
Cu | Copper | |
Cu | ⓘ Roquesite | CuInS2 |
Cu | ⓘ Chalcopyrite | CuFeS2 |
Cu | ⓘ Mawsonite | Cu6Fe2SnS8 |
Cu | ⓘ Senandorite var. Nakaseite | CuAg3Pb4Sb12S24 |
Cu | ⓘ Tetrahedrite Subgroup | Cu6(Cu4C22+)Sb4S12S |
Cu | ⓘ Freibergite Subgroup | (Ag6,[Ag6]4+)(Cu4 C22+)Sb4S12S0-1 |
Cu | ⓘ Bornite | Cu5FeS4 |
Cu | ⓘ Stannoidite | Cu6+Cu22+(Fe2+,Zn)3Sn2S12 |
Cu | ⓘ Vauquelinite | Pb2Cu(CrO4)(PO4)(OH) |
Cu | ⓘ Polybasite | [Ag6Sb2S7][Ag9CuS4] |
Cu | ⓘ Chalcocite | Cu2S |
Cu | ⓘ Djurleite | Cu31S16 |
Cu | ⓘ Tennantite Subgroup | Cu6(Cu4C22+)As4S12S |
Cu | ⓘ Stannite | Cu2FeSnS4 |
Cu | ⓘ Copper | Cu |
Cu | ⓘ Covellite | CuS |
Cu | ⓘ Brochantite | Cu4(SO4)(OH)6 |
Cu | ⓘ Emplectite | CuBiS2 |
Cu | ⓘ Aurichalcite | (Zn,Cu)5(CO3)2(OH)6 |
Cu | ⓘ Miharaite | Cu4FePbBiS6 |
Zn | Zinc | |
Zn | ⓘ Sphalerite | ZnS |
Zn | ⓘ Stannoidite | Cu6+Cu22+(Fe2+,Zn)3Sn2S12 |
Zn | ⓘ Sphalerite var. Marmatite | (Zn,Fe)S |
Zn | ⓘ Aurichalcite | (Zn,Cu)5(CO3)2(OH)6 |
As | Arsenic | |
As | ⓘ Nickeline | NiAs |
As | ⓘ Gersdorffite | NiAsS |
As | ⓘ Arsenopyrite | FeAsS |
As | ⓘ Nickelskutterudite | (Ni,Co,Fe)As3 |
As | ⓘ Annabergite | Ni3(AsO4)2 · 8H2O |
As | ⓘ Rammelsbergite | NiAs2 |
As | ⓘ Tennantite Subgroup | Cu6(Cu4C22+)As4S12S |
As | ⓘ Breithauptite var. Arite | Ni(Sb,As) |
Se | Selenium | |
Se | ⓘ Ikunolite | Bi4(S,Se)3 |
Se | ⓘ Laitakarite | Bi4Se2S |
Mo | Molybdenum | |
Mo | ⓘ Molybdenite | MoS2 |
Ag | Silver | |
Ag | ⓘ Senandorite var. Nakaseite | CuAg3Pb4Sb12S24 |
Ag | ⓘ Freibergite Subgroup | (Ag6,[Ag6]4+)(Cu4 C22+)Sb4S12S0-1 |
Ag | ⓘ Polybasite | [Ag6Sb2S7][Ag9CuS4] |
Ag | ⓘ Acanthite | Ag2S |
Ag | ⓘ Gold var. Electrum | (Au,Ag) |
Ag | ⓘ Pavonite | AgBi3S5 |
Ag | ⓘ Silver | Ag |
Ag | ⓘ Senandorite | AgPbSb3S6 |
Ag | ⓘ Stephanite | Ag5SbS4 |
In | Indium | |
In | ⓘ Roquesite | CuInS2 |
Sn | Tin | |
Sn | ⓘ Mawsonite | Cu6Fe2SnS8 |
Sn | ⓘ Stannoidite | Cu6+Cu22+(Fe2+,Zn)3Sn2S12 |
Sn | ⓘ Cassiterite | SnO2 |
Sn | ⓘ Stannite | Cu2FeSnS4 |
Sb | Antimony | |
Sb | ⓘ Senandorite var. Nakaseite | CuAg3Pb4Sb12S24 |
Sb | ⓘ Tetrahedrite Subgroup | Cu6(Cu4C22+)Sb4S12S |
Sb | ⓘ Stibnite | Sb2S3 |
Sb | ⓘ Berthierite | FeSb2S4 |
Sb | ⓘ Freibergite Subgroup | (Ag6,[Ag6]4+)(Cu4 C22+)Sb4S12S0-1 |
Sb | ⓘ Polybasite | [Ag6Sb2S7][Ag9CuS4] |
Sb | ⓘ Ullmannite | NiSbS |
Sb | ⓘ Breithauptite | NiSb |
Sb | ⓘ Breithauptite var. Arite | Ni(Sb,As) |
Sb | ⓘ Stibiconite | Sb3+Sb25+O6(OH) |
Sb | ⓘ Senandorite | AgPbSb3S6 |
Sb | ⓘ Stephanite | Ag5SbS4 |
Ba | Barium | |
Ba | ⓘ Baryte | BaSO4 |
W | Tungsten | |
W | ⓘ Scheelite | Ca(WO4) |
W | ⓘ Ferberite | FeWO4 |
Au | Gold | |
Au | ⓘ Gold | Au |
Au | ⓘ Gold var. Electrum | (Au,Ag) |
Hg | Mercury | |
Hg | ⓘ Cinnabar | HgS |
Hg | ⓘ Metacinnabar | HgS |
Pb | Lead | |
Pb | ⓘ Senandorite var. Nakaseite | CuAg3Pb4Sb12S24 |
Pb | ⓘ Vauquelinite | Pb2Cu(CrO4)(PO4)(OH) |
Pb | ⓘ Galena | PbS |
Pb | ⓘ Senandorite | AgPbSb3S6 |
Pb | ⓘ Miharaite | Cu4FePbBiS6 |
Bi | Bismuth | |
Bi | ⓘ Bismuth | Bi |
Bi | ⓘ Bismuthinite | Bi2S3 |
Bi | ⓘ Ikunolite | Bi4(S,Se)3 |
Bi | ⓘ Laitakarite | Bi4Se2S |
Bi | ⓘ Emplectite | CuBiS2 |
Bi | ⓘ Pavonite | AgBi3S5 |
Bi | ⓘ Miharaite | Cu4FePbBiS6 |
Fossils
There are 5 fossil localities from the PaleoBioDB database within this region.BETA TEST - These data are provided on an experimental basis and are taken from external databases. Mindat.org has no control currently over the accuracy of these data.
Occurrences | 96 | |||||||||||||||
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Youngest Fossil Listed | 247 Ma (Early/Lower Triassic) | |||||||||||||||
Oldest Fossil Listed | 265 Ma (Permian) | |||||||||||||||
Stratigraphic Units |
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Fossils from Region | Click here to show the list. | |||||||||||||||
Fossil Localities | Click to show 5 fossil localities |
Other Databases
Wikipedia: | https://en.wikipedia.org/wiki/Yabu,_Hy%C5%8Dgo |
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Wikidata ID: | Q869014 |
GeoNames ID: | 1848845 |
Localities in this Region
- Hyogo Prefecture
- Hyogo Prefecture
Other Regions, Features and Areas that Intersect
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Akenobe mine, Oya-cho, Yabu City, Hyogo Prefecture, Japan