Gold Science and Technology
img

Wechat

Adv. Search
Online Submission Peer Review Office Work

Gold Science and Technology ›› 2017, Vol. 25 ›› Issue (6): 1-8.doi: 10.11872/j.issn.1005-2518.2017.06.001

    Next Articles

Geochemical Characteristics and Geological Significance of Biotite in Granite Bodies of Jiajika Lithium Mine,Sichuan Province

HOU Jianglong1,LI Jiankang1,WANG Denghong1,CHEN Zhenyu1,DAI Hongzhang1,LIU Lijun 1,2   

  1. 1.MLR Key Laboratory of Metallogeny and Mineral Assessment,Institute of Mineral Resources,Chinese Academy of Geological Sciences,Beijing   100037,China;
    2.School of Earth Science and Resources,China University of Geosciences(Beijing),Beijing   100083,China
  • Received:2017-07-11 Revised:2017-08-23 Online:2017-12-30 Published:2018-05-18

PDF (PC)

917

Abstract:

Jiajika lithium deposit is a superlarge deposit in Kangding County of Sichuan Province,and it is one of the most abundant area of lithium mineral resources in China.The chemical composition of biotite in two-mica granite were analyzed by electron microprobe,and the physical and chemical conditions(such as temperature,pressure,oxygen fugacity) of two-mica granite bodies were mainly studied.The results of electron microprobe analysis show that the biotites in Jiajika two-mica granite belong to oxybiotite,and its specific type is siderophyllite.The range of w(Fe2 +)/w(Fe2 ++Mg) ratio of biotite is small,indicating that the biotite is primary bio- tite,and it is not altered by later stage reconstruction,and it can be used to estimate its physical and chemical conditions of rock formation.According to the calculation of geochemical composition of biotite,the biotite was formed under the condition of low oxygen fugacity,the crystallization temperature of biotite is between  471~541 ℃,the pressure is between 432.21~564.86 MPa.The geochemical analysis of biotite also shows that Jiajika two-mica granite belongs to aluminum granite(including collision type and S-type granite),and its formation is mainly related to crustal magma.

Key words: biotite, electron microprobe, siderophyllite, oxygen fugacity, physical and chemical conditions, aluminum granite, two-mica granite, Jiajika

CLC Number: 

  • P618.71

[1] Wang Denghong,Fu Xiaofang.Breakthrough in prospecting of the periphery of Jiajika lithium ore in Sichuan Province[J].Rock and Mineral Analysis,2013,32(6):987.[王登红,付小方.四川甲基卡外围锂矿找矿取得突破[J].岩矿测试,2013,32(6):987.]
[2] Fu Xiaofang,Hou Liwei,Wang Denghong,et al.Achievements in the investigation and evaluation of spodumene resources at Jiajika in Sichuan,China[J].Geological Survey of China,2014,1(3):38-43.[付小方,侯立玮,王登红,等.四川甘孜甲基卡锂辉石矿矿产调查评价成果[J].中国地质调查,2014,1(3):38-43.]
[3] Fu Xiaofang,Yuan Linping,Wang Denghong,et al.Mineralization characteristics and prospecting model of newly discovered X03 rare metal vein in Jiajika orefield,Sichuan[J].Mineral Deposits,2015,34(6):1172-1186.[付小方,袁蔺平,王登红,等.四川甲基卡矿田新三号稀有金属矿脉的成矿特征与勘查模型[J].矿床地质,2015,34(6):1172-1186.]
[4] Wang Denghong,Li Jiankang,Fu Xiaofang.40Ar/39Ar dating for the Jiajika pegmatite-type rare metal deposit in western Sichuan and its significance[J].Geochimica,2005,34(6):542- 547.[王登红,李建康,付小方.四川甲基卡伟晶岩型稀有金属矿床的成矿时代及其意义[J].地球化学,2005,34(6): 542-547.]
[5] Li Jiankang,Wang Denghong,Zhang Dehui,et al.The source of ore-forming fluid in Jiajika pegmatite type lithium ploymetallic deposit,Sichuan Province[J].Acta Petrologica et Mineralogica,2006,25(1):46-52.[李建康,王登红,张德会,等.四川甲基卡伟晶岩型锂多金属矿床成矿流体来源研究[J].岩石矿物学杂志,2006,25(1):46-52.]
[6] Li Jiankang,Wang Denghong,Zhang Dehui,et al.The discovery of silicate daughter mineral-bearing inclusions in the Jiajika pegmatite deposit,western Sichuan,and its significance[J].Mineral Deposits,2006,25(S):132-134.[李建康,王登红,张德会,等.川西甲基卡伟晶岩型矿床中含硅酸盐子矿物包裹体的发现及其意义[J].矿床地质,2006,25(增):132-134.]
[7] Li Jiankang,Wang Denghong,Liu Shanbao,et al.SRXRF microprobe study of fluid inclusions for pegmatite deposits in western Sichuan Province[J].Geotectonica et Metallogenia,2008,32(3):332-337.[李建康,王登红,刘善宝,等.川西伟晶岩型矿床中流体包裹体的SRXRF分析[J].大地构造与成矿学,2008,32(3):332-337.]
[8] Zhao Yuxiang,Zhao Guangming,Zeng Yifu.Geological features and genetic model for the granitic pegmatite type(Jiajika type)Li deposits in west Sichuan:By the example of the Jiajika Li deposit[J].Acta Geologica Sichuan,2015,35(3):391-395.[赵玉祥,赵光明,曾毅夫.川西甲基卡式锂矿地质特征及成矿模式[J].四川地质学报,2015,35(3):391-395.]
[9] Hao Xuefeng,Fu Xiaofang,Liang Bin,et al.Formation ages of granite and X03 pegmatite vein in Jiajika,western Sichuan,and their geological significance[J].Mineral Deposits,2015,34(6):1199-1208.[郝雪峰,付小方,梁斌,等.川西甲基卡花岗岩和新三号矿脉的形成时代及意义[J].矿床地质,2015,34(6):1199-1208.]
[10] Liu Lijun,Fu Xiaofang,Wang Denghong,et al.Geological characteristics and metallogeny of Jiajika-style rare metal deposits[J].Mineral Deposits,2015,34(6):1187-1198.[刘丽君,付小方,王登红,等.甲基卡式稀有金属矿床的地质特征与成矿规律[J].矿床地质,2015,34(6):1187-1198.]
[11] Qin Yulong,Hao Xuefeng,Xu Yunfeng,et al.Metallogenic regularity and prospecting criteria of granite type rare metal deposits in Jiajika area,Sichuan Province[J].Geological Survey of China,2015,2(7):36-39.[秦宇龙,郝雪峰,徐云峰,等.四川甲基卡地区花岗岩型稀有金属矿找矿规律及标志[J].中国地质调查,2015,2(7):36-39.]
[12] Pan Meng.Study on the Enrichment Characteristics of Lithium Element of Jiajika X03 Vein in Sichuan Province[D].Chengdu:Southwest University of Science and Technology,2015.[潘蒙.四川甲基卡X03号脉锂元素富集特征研究[D].成都:西南科技大学,2015.]
[13] Pan Meng,Tang Yi,Xiao Ruiqing,et al.The discovery of the superlarge Li ore vein X03 in the Jiajika ore district[J].Acta Geologica Sichuan,2016,36(3):422-425.[潘蒙,唐屹,肖瑞卿,等.甲基卡新3号超大型锂矿脉找矿方法[J].四川地质学报,2016,36(3):422-425.]
[14]  Liang Bin,Fu Xiaofang,Tang Yi,et al.Granite geochemical characteristics in Jiajika rare metal deposit,western Sichuan[J].Journal of Guilin University of Technology,2016, 36(1):43-49.[梁斌,付小方,唐屹,等.川西甲基卡稀有金属矿区花岗岩岩石地球化学特征[J].桂林理工大学学报,2016,36(1):43-49.]
[15] Tang Yi.Characteristics and Prospecting Significance of Granite in Jiajika Rare Metal Mining Area,Western Sichuan[D].Chengdu:Southwest University of Science and Technology,2016.[唐屹.川西甲基卡稀有金属矿区花岗岩特征及找矿意义[D].成都:西南科技大学,2016.]
[16] Xu Zhigang,Chen Yuchuan,Wang Denghong,et al.Zoning Scheme of Metallogenic Belts in China[M].Beijing:Geologcial Publishing House,2008.[徐志刚,陈毓川,王登红,等.中国成矿区带划分方案[M].北京:地质出版社,2008.]
[17] Tang Guofan,Wu Shengxian.Geological research report on carbonate rock pegmatite lithium deposit in Kangding County,Sichuan Province[R].Panzhihua:Panxi Geological Team of Sichuan Bureau of Geology and Mineral Resources,1984.[唐国凡,吴盛先.四川省康定县甲基卡花岗伟晶岩锂矿床地质研究报告[R].攀枝花:四川省地质矿产局攀西地质大队,1984.]
[18] Li J K,Wang D H,Chen Y C.The ore-forming mechanism of the Jiajika pegmatite-type rare metal deposit in western Sichuan Province:Evidence from isotope dating[J].Acta Geologica Sinica,2013,87(1):91-101.
[19] Zheng Qiaorong.Calculation of the Fe3+ and Fe2+ contents in silicate and Ti-Fe oxide minerals from EPMA data[J].Acta Mineralogica Sinica,1983(1):56-62.[郑巧荣.由电子探针分析值计算Fe3+和Fe2+[J].矿物学报,1983(1):56-62.]
[20] Zhou Zuoxia.Chemical characteristics of mafic mica in intrusive rocks and its geological meaning[J].Acta Petrologica Sinica,1988(3):63-73.[周作侠.侵入岩的镁铁云母化学成分特征及其地质意义[J].岩石学报,1988(3):63-73.]
[21] Uchida E,Endo S,Makino M.Relationship between solidification depth of granitic rocks and formation of hydro-thermal ore deposits[J].Resource Geology,2007,57(1):47-56.
[22] Henry D J,Guidotti C V,Thomson J A. The Ti-saturation surface for low-to-medium pressure metapelitic biotites:Implications for geochermometry and Ti-substitution mechanisms[J].American Mineralogist, 2005,90(2/3):316-328.
[23] Bené M,Holtz F,Luo C,et al.Biotite stability in peraluminous granitic melts:Compositional dependence and application to the generation of two-mica granites in the South Bohemian batholith(Bohemian Massif,Czech Republic)[J].Lithos,2008,102(3/4):538-553.
[24] Liu Bin,Ma Changqian,Liu Yuanyuan,et al.Mineral chemistry of biotites from the Tongshankou Cu-Mo deposit:Implications for petrogenesis and mineralization[J].Acta Petrologica et Mineralogica,2010,29(2):151-165.[刘彬,马昌前,刘园园,等.鄂东南铜山口铜(钼)矿床黑云母矿物化学特征及其对岩石成因与成矿的指示[J].岩石矿物学杂志,2010,29(2):151-165.]
[25] Wones D R,Eugster H P.Stability of biotite:Experiment,theory,and application[J].American Mineralogist,1965, 50:1228-1272.
[26] Wones D R.Significance of the assemblage titanite+magnetite+quartz in granitic rocks[J].American Mineralogist,1989,74(7):744-749.
[27] Carmichael I S E.The redox states of basic and silicic magmas:A reflection of their source regions?[J].Contributions to Mineralogy and Petrology,1991,106(2):129-141.
[28] Wilke M,Behrens H.The dependence of the partitioning of iron and europium between plagioclase and hydrous tonalitic melt on oxygen fugacity[J].Contributions to Mineralogy and Petrology,1999,137(1/2):102-114.
[29] Stussi J M,Cuney M.Nature of biotites from alkaline,calcalkaline and peraluminous magmas by abdel-fattah M.Abdel-Rahman:A comment[J].Journal of Petrology,1994, 37(2):1025-1029.
[1] Leilei ZHANG, Jing ZHANG, Qisong WANG, Liang CHEN, Xu’an CHEN. Characteristics of Pyrite from Huaishuping Gold Deposit in Xiong’ershan District and Its Geological Significance [J]. Gold Science and Technology, 2018, 26(4): 481-491.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!

©2018 Gold Science and Technology 

Telephone:0931-8277791 

E-mail: hjkx@lzb.ac.cn Postcode:730000 

Powered by Beijing Magtech Co. Ltd

陇ICP备17001318号-1