| Citation: |
WAN Xin. Analysis of Carbonatite Genesis and REE Prospecting Significance in Buru Area, Kenya[J]. Northwestern Geology, 2015, 48(1): 79-90.
|
Analysis of Carbonatite Genesis and REE Prospecting Significance in Buru Area, Kenya
-
Abstract
A number of carbonatites were discovered surrounding the Lake Victoria in Great Rift Valley of East Africa (including Buru area in Kenya). The rock is rich in rare earth elements and other microelements, so it is important to discuss its genesis and relationship with rare earth elements and other microelements. The standardized distribution curve of original mantle of Buru carbonatites is similar to that of mantle-derived carbonatite magma, it is thus suggested that the origin of carbonatite in Buru area is the earth's mantle. Behaviors of miscellaneous rocks are similar to typical mode, but there are many differences too. The order of intrusion is from ultrabasite (metabasalt) to alkaline rock(clinkstone) and carbonatite. Carbonatites were formed at low temperature and low pressure, and its lithofacies was from the volcanic facies to hypabyssal facies. Buru area in Kenya is located between the east and the west branch of East African Great Rift Valley, by stress of the earth's crust, carbonatite intruded upward from the earth's mantle. Carbonatites were formed after the late magmatic differentiation stage, through metasomatism, rare earth elements and other microelements accumulated in further. Rare earth elements and othermicroelements are richer in carbonatites such as igneous calcite carbonatite and dolomite etc., which point the prospecting direction for ore deposit of rare earth elements and other microelements. Carbonatites surrounding the Lake Victoria has very good exploration potential.-
Keywords:
- carbonatite /
- earth's mantle /
- magma intrusion /
- element enrichment /
- Buru area
-
-
References
邓希光,陈志刚.广西马山碱性杂岩交代型碳酸岩的发现及其意义[J].地学前缘,2002,9(3):216. DENG Xiguang,CHEN Zhigang. The discovery and significance of carbonatite produced by metasomatizing alkaline complex in Mashan,Guangxi[J].Earth Science Frontiers, 2002,9(3):216. 董春艳,刘敦一,万渝生,等.大青山地区元古代壳源碳酸岩:锆石特征及时性SHRIMP定年[J]. 地质学报,2009,83(3):388-398. DONG Chunyan,LIU Dunyi,WAN Yusheng,et al. Crustally derived carbonatite from the Daqinshan area:Zircon features and SHRIMP dating[J].Acta Geologica Sinica, 2009,83(3):388-398. 范宏瑞,谢奕汉,王凯怡,等.碳酸岩流体及其稀土成矿作用[J].地学前缘, 2001,8(4):289-295. FAN Hongrui,XIE Yihan,WANG Kaiyi,et al.Carbonatitic Fluids and REE Mineralization[J].Earth Science Frontiers, 2001,8(4):289-295. 李建康,白鸽,袁忠信,等.富氟钡型碳酸岩岩浆的演化机制及其成矿效应[J].地质论评, 2008,54(6):793-800. LI Jiankang,BAI Ge,YUAN Zhongxin,et al. Evolvement and ore-forming process of carbonatite magma[J].Geological review, 2008,54(6):793-800. 潘鸿迪.陕西户县大石沟碳酸岩成因分析[J].西北地质, 1997,18(2):23-29. PAN Hongdi. Analysis of genesis of dashigou carbonatite in fuxian county,shanxi province[J].Northwestern Gellogy, 1997,18(2):23-29. 任启江,胡志宏,严正富,等.矿床学概论[M]. 南京大学出版社, 1993,220. REN Qijiang,HU Zhihong,YANG Zhengfu,et al. Mineral deposits survey[M]. Nanjing:University Publishing House, 1993. 陈华,曲晓明,辛洪波,等. 西藏班公湖区含镍碳酸岩成因探讨[J].矿床地质,2010,29(6):1029-1042. CHEN Hua,QU Xiaoming,XIN Hongbo,et al.A tentative discussion on the genesis of Ni-bearing carbontites in Bangong Lake area,Tibet[J].Mineral Deposits,2010,29(6):1029-1042. 宋文磊,许成,刘琼.火成碳酸岩的实验岩石学研究及对地球深部碳循环的意义[J]. 地质论评,2012,58(4):726-744. SONG Wenrui,XU Cheng,LIU Qiong. Experimental Petrological Study of Carbonatite and Its Significances on the Earth Deep Carbon Cycle[J].Geological Review, 2012,58(4):726-744 (in Chinese with English abstract). 孙宝生,周可法.新疆且干布拉克超基性岩碳酸岩杂岩体地质特征和地球化学研究[J]. 干旱区地理,2008,31(5):633-642. SUN Baosheng,ZHOU Kefa.Charactistics of qie gan bulak ultrabasic-carbonatite complex in Xin Jiang,China and its geochemistry[J].Arid Land Geography, 2008,31(5):633-642. 肖荣阁,刘敬党,费红彩.白云鄂博REE-Nb—Fe矿床的富钠岩石类型及成因分析[J]. 现代地质,2006,20(1):151-162. XIAO Rongge,LIU Jingdang,FEI Hongcai,et al. Types and Genesis of Na-Rich Rocks in the Bayan Obo REE-Nb-Fe Deposit, Inner Mongolia, China [J].Geoscience, 2006,20(1):151-162. 阎国翰,牟保磊,曾贻善,等.华北克拉通火成碳酸岩时空分布和锶钕同位素特征及其地质意义[J]. 高校地质学报,2007,13(3):463-473. YAN Guohan,MU Baolei, ZENG Yishan,et al. Igneous Carbonatites in North China Craton: The Temporal and Spatial Distribution, Sr and Nd Isotopic Charateristics and Their Geological Significance[J]. Geological Journal of China Universities, 2007,13(3):463-473. 喻学惠,张春福.甘肃西秦岭新生代碱性火山岩的Sr,Nd 同位素及微量元素地球化学特征[J].地学前缘,1998,5(4):319-327. YU Xuehui,ZHANG Chunhu. Sr,Nd isotope and trace elements geochemical features of the Cenozoic volcanic rocks from west qinling gansu province[J].Earth science Frontiers. 1998,5(4):319-327. 周振玲,李功元,宋同云.内蒙古白云鄂博白云石碳酸岩的地质特征及其成因探讨[J]. 地质论评,1980,26(1):35-41. ZHOU Zhenlin,LI Gongyuan,SONG Tongyun. Geological character and genesis of carbonatite in Bayan obo, Inner Mongolia[J]. Geological Review, 1980, 26(1):35-41 (in Chinese with English abstract). 赵斌,赵劲松,汪劲革,等.一种可能的新碳酸岩类型:壳源成因碳酸岩[J]. 地球化学,2004,33(6):649-662. ZHAO Bin,ZHAO Jingsong,WUANG Jing, et al.A Possible new carbonatite type:Crust-detived carbonatite[J].Geochemica,2004.33(6):649-662. BROOKER R A and HAMILTON D L. Three-liquid immiscibility and the origin of carbonatites[J].Nature, 1990,346:459-462. DALTON J A,PRENALL D C and DEAN C. The continuum of primary carbonatite-Kimber Litic melt compositions in equilibrium with cherzolite data from the system CaO-MgO-Al2O3-CO2 at 6 GPa[J].Journal of Petrology, 1998,39:1953-1964. DENENY A,CASILLAS R, AGUSTINA A, et al. carbonate xenoliths inLa Palma :Carbonatite or alteration product[J].Chemie der Erde, 2008,68:369-381. FREESFONE I C,HAMILTON D L. The role of liquid immiscibility in the genesis of carbonates-an experimental study[J].Contrib.Mineral.Petrol, 1980,73:105-117. HARMER R, GITTINS J. The case for primary,mantle=derived carbonatite magma[J].Journal of Petrology, 1998,39:1895-1903. HALMA R, VENNEMANN T,SIEBEL W,et al. The Gronnedal-Ika carbonatite-stemitecomplex,south Greenland:Carbonatite foromation by liquid immiscibility[J]. Journal of Petrology, 2005,46:191-217. KIARSGSSRD B A, HAMILTON D L. Liquid immiscibility and the origin of alkal-poor carbonatite[J].Mineral.Mag, 1988,52:43-55. LENTZ D R. Carbontite genesis:A reexamination of the role of instrusion-related pneumatolytic sharn processes in Limestone melting[J].Geology, 1999,27(4):127-130. PANINA PI,MOTORINA I V. Liquid Immiscibility in Deep-Seated Magmas and the Generation of Carbonatite Melts[J]. Geochemistry International,2008,46(54):448-464. RANKIN A H,LE BAS M J. Liquid immiscibility between silicate and carbonate melts in naturally occurring ijolite magma[J].Nature, 1974,250:206-209. RANKIN A H. Fluid inclusion studies in apatite from carbonatites of the Wasaki of Western Kenya[J].Lithos, 1975,8:123-136. SMITH M P,HENDERSON P. Preliminary fluid inclusion constraints on fluid evolution in the Bayan obo Fe-REE-Nb deposit,innerMongolia,china[J].Economic Geology, 2000,95:137-138. VEKSLER I V,Petibon C M,JENNER G A,et al. Trace elementpartitioning in immi-scible silicate-carbonate liquid systems;An initial experimental study using a centrifuge autocalave [J].Journal of Petrology, 1998,39:2095-2104. WAN Yusheng,LIU Dunyi,XU Zhongyuan,et al. Paleoproterozoic crustally derived carbontite from the Daqinshan area,North China Carton:Geological,petrographical,geochronological and geochemical (Hf,Nd, O and C)evidence [J].Journal of American Science(in press). WILLIAMS J Ones A E,Wood SA. A Preliminary petrogenetic grid for REE flurocarbonates and associated minerals[J].Geochim Cosmochim Acta, 1992,56:725-738. WYLLIE P J, HUANG W L. Carbonation and melting reactions in the system CaO-MgO-SiO-CO at mantle pressures with geophysical and petrological applications[J].Contrib Mineral Petrol, 1976,54:79-107. Report on the Mineral Eeploration in the Homa Baby Area[R]. 日本国际合作机构(JICA),金属矿业机构(MMAJ). -
Access History
Export File
Citation
WAN Xin. Analysis of Carbonatite Genesis and REE Prospecting Significance in Buru Area, Kenya[J]. Northwestern Geology, 2015, 48(1): 79-90.
DownLoad: