Jeju Province, South Koreai
Regional Level Types | |
---|---|
Jeju Province | Province |
South Korea | Country |
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Area:
1,149 km2
Neighbouring regions:
Locality type:
Province - last checked 2019
Other/historical names associated with this locality:
Cheju-do; Jejudo; Jeju Island; Jeju Island
Other Languages:
French:
Jeju, Corée du Sud
German:
Jeju-do, Südkorea
Italian:
Jeju-do, Corea del Sud
Korean:
제주특별자치도, 대한민국
Russian:
Чеджудо, Республика Корея
Simplified Chinese:
濟州特別自治道, 大韩民国
Spanish:
Jeju-do, Corea del Sur
Achinese:
Jeju, Korèa Seulatan
Arabic:
جيجو , كوريا الجنوبية
Armenian:
Ջեջու նահանգ, Հարավային Կորեա
Azeri:
Çejudo adası, Cənubi Koreya
Basque:
Jeju, Hego Korea
Belarusian:
Чэджуда, Паўднёвая Карэя
Bengali:
জেজু দ্বীপ, দক্ষিণ কোরিয়া
Bulgarian:
Чеджу-до, Южна Корея
Catalan:
Jeju-do, Corea del Sud
Cebuano:
Jeju-do, Habagatang Korea
Chuvash:
Чеджу
Classical Chinese:
濟州, 大韓民國
Croatian:
Jeju, Južna Koreja
Czech:
Čedžu, Jižní Korea
Danish:
Jeju-do, Sydkorea
Dutch:
Jeju-do, Zuid-Korea
Esperanto:
Jeju-do, Sud-Koreio
Estonian:
Jeju provints, Lõuna-Korea
Farsi/Persian:
ججو-دو, کره جنوبی
Finnish:
Jeju, Korean tasavalta
Galician:
Jeju, Corea do Sur
Greek:
Τζετζού, Νότια Κορέα
Gujarati:
જેજુ, દક્ષિણ કોરિયા
Hakka:
Jeju Thi̍t-phe̍t Chhṳ-chhṳ-tho, Thai-hòn Mìn-koet
Hebrew:
ג'ג'ו, קוריאה הדרומית
Hindi:
जेजू, दक्षिण कोरिया
Hungarian:
Csedzsu-sziget, Dél-Korea
Ido:
Jeju insulo, Sud-Korea
Iloko:
Provincia ti Jeju, Abagatan a Korea
Indonesian:
Jeju, Korea Selatan
Interlingua:
Jeju-do, Corea del Sud
Japanese:
済州特別自治道, 大韓民国
Javanese:
Jejudo, Koréa Kidul
Kannada:
ಜೆಜು, ದಕ್ಷಿಣ ಕೊರಿಯಾ
Kapampangan:
Lalawigan ning Jeju, Mauling Korea
Kazakh (Cyrillic Script):
Чеджудо, Корея Республикасы
Latvian:
Čendžu, Dienvidkoreja
Lingua Franca Nova:
Jeju-do, Tehan
Lithuanian:
Čedžu, Pietų Korėja
Macedonian:
Чеџу, Јужна Кореја
Malay:
Jeju, Korea Selatan
Marathi:
जेजू, दक्षिण कोरिया
Min Dong Chinese:
Jeju Dĕk-biék Cê̤ṳ-dé-dô̤, Dâi-hàng Mìng-guók
Minnan / Hokkien-Taiwanese:
Jeju Te̍k-pia̍t Chū-tī-tō, Hân-kok
Nepali:
जेजु प्रान्त, दक्षिण कोरिया
Norwegian:
Jeju, Sør-Korea
Occitan:
Jeju-do, Corèa del Sud
Ossetian:
Чеджудо, Республикæ Корей
Polish:
Czedżu, Korea Południowa
Portuguese:
Jeju, Coreia do Sul
Romanian:
Insula Jeju, Coreea de Sud
Scots:
Jeju-do, Sooth Korea
Serbian:
Чеџу, Јужна Кореја
Sinhalese:
ජෙජු දූපත, දකුණු කොරියාව
Swahili:
Jeju-do, Korea Kusini
Swedish:
Jeju, Sydkorea
Tagalog:
Lalawigan ng Jeju, Timog Korea
Tamil:
ஜேஜூ, தென் கொரியா
Telugu:
జేజూ, దక్షిణ కొరియా
Thai:
จังหวัดเชจู, ประเทศเกาหลีใต้
Traditional Chinese:
濟州特別自治道, 大韓民國
Turkish:
Jeju, Güney Kore
Ukrainian:
Чеджу , Південна Корея
Urdu:
جیجو صوبہ, جنوبی کوریا
Vietnamese:
Jeju, Hàn Quốc
Waray:
Jeju-do, Salatan nga Korea
Western Punjabi:
جیجو جزیرہ, دکھنی کوریا
Wu Chinese:
济州特别自治道, 大韩民国
Quelpart (name used by Westerners for the island until ~1930); Saishu-to (Japanese)
The island consists of a lava plateau, on which a shield volcano rising to 1950 m, together with c. 360 scoria and composite cones and phreatomagmatic eruption centres. The principal volcano, Mount Hallasan has a crater from which most of the lavas covering the island erupted.
Select Mineral List Type
Standard Detailed Gallery Strunz Chemical ElementsMineral List
12 valid minerals.
Rock Types Recorded
Note: data is currently VERY limited. Please bear with us while we work towards adding this information!
Select Rock List Type
Alphabetical List Tree DiagramDetailed Mineral List:
ⓘ Aegirine-augite Formula: (NaaCabFe2+cMgd)(Fe3+eAlfFe2+gMgh)Si2O6 Reference: Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155 |
ⓘ Albite Formula: Na(AlSi3O8) Reference: Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155 |
ⓘ Albite var. Anorthoclase Formula: (Na,K)AlSi3O8 Reference: Lee, M.W. (1982) journal of the Japan Association of Mineralogists, Petrologists and Economic Geologists, 77, 203-214. |
ⓘ Albite var. Oligoclase Formula: (Na,Ca)[Al(Si,Al)Si2O8] Reference: Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155 |
ⓘ 'Alkali Feldspar' Reference: Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155 |
ⓘ 'Amphibole Supergroup' Formula: AB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2 Reference: Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155 |
ⓘ Anorthite Formula: Ca(Al2Si2O8) Reference: Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155 |
ⓘ Anorthite var. Bytownite Formula: (Ca,Na)[Al(Al,Si)Si2O8] Reference: Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155 |
ⓘ Anorthite var. Labradorite Formula: (Ca,Na)[Al(Al,Si)Si2O8] Reference: Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155 |
ⓘ 'Apatite' Formula: Ca5(PO4)3(Cl/F/OH) Reference: Lee, M.W. (1982) journal of the Japan Association of Mineralogists, Petrologists and Economic Geologists, 77, 203-214.; Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155 |
ⓘ Augite Formula: (CaxMgyFez)(Mgy1Fez1)Si2O6 Reference: Lee, M.W. (1982) journal of the Japan Association of Mineralogists, Petrologists and Economic Geologists, 77, 203-214.; Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155 |
ⓘ Augite var. Ferroaugite Reference: Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155 |
ⓘ 'Clinopyroxene Subgroup' Reference: Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155 |
ⓘ Diopside Formula: CaMgSi2O6 Reference: Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155 |
ⓘ 'Diopside-Hedenbergite Series' Reference: Lee, M.W. (1982) journal of the Japan Association of Mineralogists, Petrologists and Economic Geologists, 77, 203-214. |
ⓘ 'Fayalite-Forsterite Series' Reference: Lee, M.W. (1982) journal of the Japan Association of Mineralogists, Petrologists and Economic Geologists, 77, 203-214.; Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155; Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155 |
ⓘ Ferrosilite Formula: FeSiO3 Reference: Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155 |
ⓘ Forsterite Formula: Mg2SiO4 Reference: s.j.kim. science of mineral |
ⓘ Forsterite var. Peridot Formula: Mg2SiO4 Reference: s.j.kim. science of mineral |
ⓘ Hedenbergite Formula: CaFe2+Si2O6 Reference: Lee, M.W. (1982) journal of the Japan Association of Mineralogists, Petrologists and Economic Geologists, 77, 203-214.; Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155 |
ⓘ Hedenbergite var. Ferrosalite Reference: Lee, M.W. (1982) journal of the Japan Association of Mineralogists, Petrologists and Economic Geologists, 77, 203-214. |
ⓘ Ilmenite Formula: Fe2+TiO3 Reference: Lee, M.W. (1982) journal of the Japan Association of Mineralogists, Petrologists and Economic Geologists, 77, 203-214. |
ⓘ Kaersutite Formula: NaCa2(Mg3AlTi4+)(Si6Al2)O22O2 Reference: Lee, M.W. (1982) journal of the Japan Association of Mineralogists, Petrologists and Economic Geologists, 77, 203-214. |
ⓘ Magnetite Formula: Fe2+Fe3+2O4 Reference: Lee, M.W. (1982) journal of the Japan Association of Mineralogists, Petrologists and Economic Geologists, 77, 203-214.; Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155 |
ⓘ Magnetite var. Titanium-bearing Magnetite Formula: Fe2+(Fe3+,Ti)2O4 Reference: Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155 |
ⓘ 'Microlite Group' Formula: A2-mTa2X6-wZ-n Reference: Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155 |
ⓘ 'Plagioclase' Formula: (Na,Ca)[(Si,Al)AlSi2]O8 Reference: Lee, M.W. (1982) journal of the Japan Association of Mineralogists, Petrologists and Economic Geologists, 77, 203-214.; Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155 |
ⓘ 'Pyroxene Group' Formula: ADSi2O6 Reference: Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155 |
ⓘ Rhönite Formula: Ca4[Mg8Fe3+2Ti2]O4[Si6Al6O36] Reference: Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155 |
Gallery:
List of minerals arranged by Strunz 10th Edition classification
Group 4 - Oxides and Hydroxides | |||
---|---|---|---|
ⓘ | Ilmenite | 4.CB.05 | Fe2+TiO3 |
ⓘ | Magnetite | 4.BB.05 | Fe2+Fe3+2O4 |
ⓘ | var. Titanium-bearing Magnetite | 4.BB.05 | Fe2+(Fe3+,Ti)2O4 |
ⓘ | 'Microlite Group' | 4.00. | A2-mTa2X6-wZ-n |
Group 9 - Silicates | |||
ⓘ | Aegirine-augite | 9.DA.20 | (NaaCabFe2+cMgd)(Fe3+eAlfFe2+gMgh)Si2O6 |
ⓘ | Albite | 9.FA.35 | Na(AlSi3O8) |
ⓘ | var. Anorthoclase | 9.FA.35 | (Na,K)AlSi3O8 |
ⓘ | var. Oligoclase | 9.FA.35 | (Na,Ca)[Al(Si,Al)Si2O8] |
ⓘ | Anorthite | 9.FA.35 | Ca(Al2Si2O8) |
ⓘ | var. Bytownite | 9.FA.35 | (Ca,Na)[Al(Al,Si)Si2O8] |
ⓘ | var. Labradorite | 9.FA.35 | (Ca,Na)[Al(Al,Si)Si2O8] |
ⓘ | Augite | 9.DA.15 | (CaxMgyFez)(Mgy1Fez1)Si2O6 |
ⓘ | var. Ferroaugite | 9.DA.15 | (CaxMgyFez)(Mgy1Fez1)Si2O6 |
ⓘ | Diopside | 9.DA.15 | CaMgSi2O6 |
ⓘ | Ferrosilite | 9.DA.05 | FeSiO3 |
ⓘ | Forsterite | 9.AC.05 | Mg2SiO4 |
ⓘ | var. Peridot | 9.AC.05 | Mg2SiO4 |
ⓘ | Hedenbergite | 9.DA.15 | CaFe2+Si2O6 |
ⓘ | var. Ferrosalite | 9.DA.15 | CaFe2+Si2O6 |
ⓘ | Kaersutite | 9.DE.15 | NaCa2(Mg3AlTi4+)(Si6Al2)O22O2 |
ⓘ | Rhönite | 9.DH.40 | Ca4[Mg8Fe3+2Ti2]O4[Si6Al6O36] |
Unclassified Minerals, Rocks, etc. | |||
ⓘ | 'Alkali Feldspar' | - | |
ⓘ | 'Amphibole Supergroup' | - | AB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2 |
ⓘ | 'Apatite' | - | Ca5(PO4)3(Cl/F/OH) |
ⓘ | 'Clinopyroxene Subgroup' | - | |
ⓘ | 'Diopside-Hedenbergite Series' | - | |
ⓘ | 'Fayalite-Forsterite Series' | - | |
ⓘ | 'Plagioclase' | - | (Na,Ca)[(Si,Al)AlSi2]O8 |
ⓘ | 'Pyroxene Group' | - | ADSi2O6 |
List of minerals for each chemical element
H | Hydrogen | |
---|---|---|
H | ⓘ Apatite | Ca5(PO4)3(Cl/F/OH) |
H | ⓘ Amphibole Supergroup | AB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2 |
O | Oxygen | |
O | ⓘ Plagioclase | (Na,Ca)[(Si,Al)AlSi2]O8 |
O | ⓘ Augite | (CaxMgyFez)(Mgy1Fez1)Si2O6 |
O | ⓘ Albite var. Anorthoclase | (Na,K)AlSi3O8 |
O | ⓘ Magnetite | Fe2+Fe23+O4 |
O | ⓘ Ilmenite | Fe2+TiO3 |
O | ⓘ Apatite | Ca5(PO4)3(Cl/F/OH) |
O | ⓘ Hedenbergite | CaFe2+Si2O6 |
O | ⓘ Kaersutite | NaCa2(Mg3AlTi4+)(Si6Al2)O22O2 |
O | ⓘ Anorthite var. Labradorite | (Ca,Na)[Al(Al,Si)Si2O8] |
O | ⓘ Anorthite var. Bytownite | (Ca,Na)[Al(Al,Si)Si2O8] |
O | ⓘ Diopside | CaMgSi2O6 |
O | ⓘ Magnetite var. Titanium-bearing Magnetite | Fe2+(Fe3+,Ti)2O4 |
O | ⓘ Albite var. Oligoclase | (Na,Ca)[Al(Si,Al)Si2O8] |
O | ⓘ Pyroxene Group | ADSi2O6 |
O | ⓘ Ferrosilite | FeSiO3 |
O | ⓘ Aegirine-augite | (NaaCabFec2+Mgd)(Fee3+AlfFeg2+Mgh)Si2O6 |
O | ⓘ Rhönite | Ca4[Mg8Fe23+Ti2]O4[Si6Al6O36] |
O | ⓘ Amphibole Supergroup | AB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2 |
O | ⓘ Anorthite | Ca(Al2Si2O8) |
O | ⓘ Albite | Na(AlSi3O8) |
O | ⓘ Forsterite var. Peridot | Mg2SiO4 |
O | ⓘ Forsterite | Mg2SiO4 |
F | Fluorine | |
F | ⓘ Apatite | Ca5(PO4)3(Cl/F/OH) |
F | ⓘ Amphibole Supergroup | AB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2 |
Na | Sodium | |
Na | ⓘ Plagioclase | (Na,Ca)[(Si,Al)AlSi2]O8 |
Na | ⓘ Albite var. Anorthoclase | (Na,K)AlSi3O8 |
Na | ⓘ Kaersutite | NaCa2(Mg3AlTi4+)(Si6Al2)O22O2 |
Na | ⓘ Anorthite var. Labradorite | (Ca,Na)[Al(Al,Si)Si2O8] |
Na | ⓘ Anorthite var. Bytownite | (Ca,Na)[Al(Al,Si)Si2O8] |
Na | ⓘ Albite var. Oligoclase | (Na,Ca)[Al(Si,Al)Si2O8] |
Na | ⓘ Aegirine-augite | (NaaCabFec2+Mgd)(Fee3+AlfFeg2+Mgh)Si2O6 |
Na | ⓘ Albite | Na(AlSi3O8) |
Mg | Magnesium | |
Mg | ⓘ Augite | (CaxMgyFez)(Mgy1Fez1)Si2O6 |
Mg | ⓘ Kaersutite | NaCa2(Mg3AlTi4+)(Si6Al2)O22O2 |
Mg | ⓘ Diopside | CaMgSi2O6 |
Mg | ⓘ Aegirine-augite | (NaaCabFec2+Mgd)(Fee3+AlfFeg2+Mgh)Si2O6 |
Mg | ⓘ Rhönite | Ca4[Mg8Fe23+Ti2]O4[Si6Al6O36] |
Mg | ⓘ Forsterite var. Peridot | Mg2SiO4 |
Mg | ⓘ Forsterite | Mg2SiO4 |
Al | Aluminium | |
Al | ⓘ Plagioclase | (Na,Ca)[(Si,Al)AlSi2]O8 |
Al | ⓘ Albite var. Anorthoclase | (Na,K)AlSi3O8 |
Al | ⓘ Kaersutite | NaCa2(Mg3AlTi4+)(Si6Al2)O22O2 |
Al | ⓘ Anorthite var. Labradorite | (Ca,Na)[Al(Al,Si)Si2O8] |
Al | ⓘ Anorthite var. Bytownite | (Ca,Na)[Al(Al,Si)Si2O8] |
Al | ⓘ Albite var. Oligoclase | (Na,Ca)[Al(Si,Al)Si2O8] |
Al | ⓘ Aegirine-augite | (NaaCabFec2+Mgd)(Fee3+AlfFeg2+Mgh)Si2O6 |
Al | ⓘ Rhönite | Ca4[Mg8Fe23+Ti2]O4[Si6Al6O36] |
Al | ⓘ Amphibole Supergroup | AB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2 |
Al | ⓘ Anorthite | Ca(Al2Si2O8) |
Al | ⓘ Albite | Na(AlSi3O8) |
Si | Silicon | |
Si | ⓘ Plagioclase | (Na,Ca)[(Si,Al)AlSi2]O8 |
Si | ⓘ Augite | (CaxMgyFez)(Mgy1Fez1)Si2O6 |
Si | ⓘ Albite var. Anorthoclase | (Na,K)AlSi3O8 |
Si | ⓘ Hedenbergite | CaFe2+Si2O6 |
Si | ⓘ Kaersutite | NaCa2(Mg3AlTi4+)(Si6Al2)O22O2 |
Si | ⓘ Anorthite var. Labradorite | (Ca,Na)[Al(Al,Si)Si2O8] |
Si | ⓘ Anorthite var. Bytownite | (Ca,Na)[Al(Al,Si)Si2O8] |
Si | ⓘ Diopside | CaMgSi2O6 |
Si | ⓘ Albite var. Oligoclase | (Na,Ca)[Al(Si,Al)Si2O8] |
Si | ⓘ Pyroxene Group | ADSi2O6 |
Si | ⓘ Ferrosilite | FeSiO3 |
Si | ⓘ Aegirine-augite | (NaaCabFec2+Mgd)(Fee3+AlfFeg2+Mgh)Si2O6 |
Si | ⓘ Rhönite | Ca4[Mg8Fe23+Ti2]O4[Si6Al6O36] |
Si | ⓘ Amphibole Supergroup | AB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2 |
Si | ⓘ Anorthite | Ca(Al2Si2O8) |
Si | ⓘ Albite | Na(AlSi3O8) |
Si | ⓘ Forsterite var. Peridot | Mg2SiO4 |
Si | ⓘ Forsterite | Mg2SiO4 |
P | Phosphorus | |
P | ⓘ Apatite | Ca5(PO4)3(Cl/F/OH) |
Cl | Chlorine | |
Cl | ⓘ Apatite | Ca5(PO4)3(Cl/F/OH) |
Cl | ⓘ Amphibole Supergroup | AB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2 |
K | Potassium | |
K | ⓘ Albite var. Anorthoclase | (Na,K)AlSi3O8 |
Ca | Calcium | |
Ca | ⓘ Plagioclase | (Na,Ca)[(Si,Al)AlSi2]O8 |
Ca | ⓘ Augite | (CaxMgyFez)(Mgy1Fez1)Si2O6 |
Ca | ⓘ Apatite | Ca5(PO4)3(Cl/F/OH) |
Ca | ⓘ Hedenbergite | CaFe2+Si2O6 |
Ca | ⓘ Kaersutite | NaCa2(Mg3AlTi4+)(Si6Al2)O22O2 |
Ca | ⓘ Anorthite var. Labradorite | (Ca,Na)[Al(Al,Si)Si2O8] |
Ca | ⓘ Anorthite var. Bytownite | (Ca,Na)[Al(Al,Si)Si2O8] |
Ca | ⓘ Diopside | CaMgSi2O6 |
Ca | ⓘ Albite var. Oligoclase | (Na,Ca)[Al(Si,Al)Si2O8] |
Ca | ⓘ Aegirine-augite | (NaaCabFec2+Mgd)(Fee3+AlfFeg2+Mgh)Si2O6 |
Ca | ⓘ Rhönite | Ca4[Mg8Fe23+Ti2]O4[Si6Al6O36] |
Ca | ⓘ Anorthite | Ca(Al2Si2O8) |
Ti | Titanium | |
Ti | ⓘ Ilmenite | Fe2+TiO3 |
Ti | ⓘ Kaersutite | NaCa2(Mg3AlTi4+)(Si6Al2)O22O2 |
Ti | ⓘ Magnetite var. Titanium-bearing Magnetite | Fe2+(Fe3+,Ti)2O4 |
Ti | ⓘ Rhönite | Ca4[Mg8Fe23+Ti2]O4[Si6Al6O36] |
Ti | ⓘ Amphibole Supergroup | AB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2 |
Fe | Iron | |
Fe | ⓘ Augite | (CaxMgyFez)(Mgy1Fez1)Si2O6 |
Fe | ⓘ Magnetite | Fe2+Fe23+O4 |
Fe | ⓘ Ilmenite | Fe2+TiO3 |
Fe | ⓘ Hedenbergite | CaFe2+Si2O6 |
Fe | ⓘ Magnetite var. Titanium-bearing Magnetite | Fe2+(Fe3+,Ti)2O4 |
Fe | ⓘ Ferrosilite | FeSiO3 |
Fe | ⓘ Aegirine-augite | (NaaCabFec2+Mgd)(Fee3+AlfFeg2+Mgh)Si2O6 |
Fe | ⓘ Rhönite | Ca4[Mg8Fe23+Ti2]O4[Si6Al6O36] |
Ta | Tantalum | |
Ta | ⓘ Microlite Group | A2-mTa2X6-wZ-n |
Geochronology
Mineralization age: Pleistocene : 0.733 ± 0.056 Ma to 0.025 ± 0.008 MaImportant 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.
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Fossils
This region is too big to display the fossil list, try looking at smaller subregions.References
Sort by
Year (asc) Year (desc) Author (A-Z) Author (Z-A)Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.155
Lee, D.S. (ed) 1988. Geology of Korea. Kyohak-Sa Publishing, Seoul.
Brenna, M., Cronin, S. J., Smith, I. E., Sohn, Y. K., & Maas, R. (2012). Spatio-temporal evolution of a dispersed magmatic system and its implications for volcano growth, Jeju Island Volcanic Field, Korea. Lithos, 148, 337-352.
Choi, S. H., Jwa, Y. J., & Lee, H. Y. (2001). Geothermal gradient of the upper mantle beneath Jeju Island, Korea: Evidence from mantle xenoliths. Island arc, 10(2), 175-193.
Haraguchi, K. (1931). Saishu volcano. Bulletin of the Geological Survey of Chosen (Korea), 10, 1-12.
Tatsumi, Y., Shukuno, H., Yoshikawa, M., Chang, Q., Sato, K., & Lee, M. W. (2005). The petrology and geochemistry of volcanic rocks on Jeju Island: plume magmatism along the Asian continental margin. Journal of Petrology, 46(3), 523-553.
Won, J. K., Matsuda, J. I., Nagao, K., Kim, K. H., & Lee, M. W. (1986). Paleomagnetism and radiometric age of trachytes in Jeju Island, Korea. Economic and Environmental Geology, 19(1), 25-33.
Yang, K., Arai, S., Yu, J. E., Yun, S. H., Kim, J. S., & Hwang, J. Y. (2012). Gabbroic xenoliths and megacrysts in the Pleisto-Holocene alkali basalts from Jeju Island, South Korea: The implications for metasomatism of the lower continental crust. Lithos, 142, 201-215.
Other Databases
Wikipedia: | https://en.wikipedia.org/wiki/Jeju_Province |
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Wikidata ID: | Q41164 |
GeoNames ID: | 1846265 |
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