吉林大学学报(地球科学版) ›› 2017, Vol. 47 ›› Issue (4): 1083-1103.doi: 10.13278/j.cnki.jjuese.201704110

• 地质与资源 • 上一篇    下一篇

非洲中南部铜多金属矿床研究现状及找矿潜力分析

任军平, 王杰, 刘晓阳, 贺福清, 何胜飞, 左立波, 许康康, 龚鹏辉, 孙凯, 刘宇   

  1. 中国地质调查局天津地质调查中心, 天津 300170
  • 收稿日期:2016-11-01 出版日期:2017-07-26 发布日期:2017-07-26
  • 作者简介:任军平(1980),男,高级工程师,主要从事地质矿产勘查方面研究,E-mail:rjp2333@126.com
  • 基金资助:
    中国地质调查局项目(1212011220910);中央地勘基金国外矿产资源风险勘查专项([2011]D3-04);商务部技术援外项目([2012]558)

Research Status and Prospecting Potential of Copper Polymetallic Deposits in Central-South Africa

Ren Junping, Wang Jie, Liu Xiaoyang, He Fuqing, He Shengfei, Zuo Libo, Xu Kangkang, Gong Penghui, Sun Kai, Liu Yu   

  1. Tianjin Center, China Geological Survey, Tianjin 300170, China
  • Received:2016-11-01 Online:2017-07-26 Published:2017-07-26
  • Supported by:
    Supported by Project of China Gcological Survey(1212011220910),Foreign Risk Exploration Project of Central Geolo-gical Prospecting Fund([2011]D3-04)and Technical Aid Project of the Ministry of Commerce([2012]558)

摘要: 非洲中南部地区的铜资源主要分布在赞比亚、刚果(金) 和南非等12个国家,笔者根据非洲陆壳的形成、后期新元古代泛非运动及古生代—新生代的沉积作用等影响,将除非洲大陆西北缘,从摩洛哥到突尼斯的阿特拉斯山脉以外的非洲大陆划分为Ⅰ级构造单元;以新元古代泛非运动作为标志将非洲陆块划分为西非克拉通、东北非克拉通、中非克拉通、南非克拉通和泛非构造带5个Ⅱ级构造单元;将中南部非洲地区划分为28个Ⅲ级构造单元。在此基础上,笔者将非洲大陆划分为Ⅰ级成矿域,中南部非洲划分为南非克拉通金-铁-锰-铬-镍-铀-金刚石成矿省、中非克拉通金-铜-铁-钨-锡-铌-钽-金刚石成矿省和泛非构造带成矿省3个Ⅱ级成矿省及32个Ⅲ级成矿区(带),其中12个成矿区(带)与铜矿床有关。从地质特征及矿床成因方面对主要成矿区(带)中代表性的沉积变质-改造型铜钴矿床、与镁铁—超镁铁岩侵入体有关的铜镍矿床、与绿岩带有关的铜矿床、与碳酸岩体有关的铜矿床和与灰岩有关的铜多金属矿床进行了系统的总结。在缺乏重点地区物化探资料的条件下,笔者根据非洲中南部铜资源分布的国家、构造单元的划分、成矿区(带)的划分及代表性矿床特征,将非洲中南部地区初步划分为5个铜多金属矿找矿潜力区,并进行了初步的找矿潜力分析。

关键词: 铜多金属矿床, 研究现状, 成矿潜力分析, 非洲中南部

Abstract: Copper resources in the Southern and Central Africa are mainly distributed in 12 countries such as Zambia, DR Congo, and South Africa. Based on the study of the formation of African continent, subsequent Neoproterozoic pan-African movement, and Paleozoic-Cenozoic sedimentation, the authors suggest that apart from the northwestern margin of the continent, namely the region from the Morocco to Atlas mountains in Tunisia, the African continent is a grade Ⅰ tectonic unit, and which can be broken down into 5 grade Ⅱ and 28 grade Ⅲ tectonic units by taking the Neoproterozoic pan-African movement as a marker. The 5 gradeⅡtectonic units include the Western African craton, the Eastern African craton, the Central African craton, the Southern African craton, and the pan-African structural belt; on the basis of the above tectonic breakdown, the whole African continent is suggested to be the grade Ⅰ metallogenic domain, and which is divided into 3 grade Ⅱ metallogenic provinces and 32 grade Ⅲ metallogenic regions(belts). 12 of them are related to copper deposits. The 3 metallogenic provinces include Au-Fe-Mn-Cr-Ni-U and diamond metallogenic province in the Southern African craton, Au-Cu-Fe-W-Sn-Nb-Ta and diamond metallogenic province in the Central African craton, and the metallogenic province in pan-African tectonic belt. A preliminary analysis was conducted. Based on the results of geological characteristics and mineralization setting, a summary of the typical ore deposits in the major metallogenic regions (belts) is given in this paper to cover a variety of deposits such as sedimentary metamorphic-reformed Cu-Co deposits, mafic and ultramafic intrusive related Cu-Ni deposits, greenstone belt related copper deposits, carbonate rock related copper deposits, and copper polymetallic deposits associated with limestone. According to the distribution of copper resources, the breakdown of tectonic units, the metallogenic regions (belts), and the characteristics of representative deposits, the authors divide the central and Southern Africa into five potential copper polymetallic ore prospecting areas.

Key words: copper polymetallic deposits, research status, metallogenic potential analysis, Central-Southern Africa

中图分类号: 

  • P618.4
[1] 佚名.中企海外矿业投资还在蹒跚学步[EB/OL].(2014-07-08)[2016-03-05]. http://www.mlr.gov.cn/xwdt/kyxw/201407/t20140708_1323055.htm. Anonymity. Overseas Mining Investment of Chinese Mining Enterprises was Still a Toddler [EB/OL].(2014-07-08)[2016-03-05]. http://www.mlr.gov.cn/xwdt/kyxw/201407/t20140708_1323055.htm.
[2] 中国矿业联合会. 2014年中国企业境外固体矿产投资报告[EB/OL].(2015-02-09) [2016-03-05]. http://www.ceweekly.cn/2015/0209/103895.shtml. China Mining Association. Report on China's Overseas Solid Mineral Investment in 2014[EB/OL].(2015-02-09)[2016-03-05]. http://www.ceweekly.cn/2015/0209/103895.shtml.
[3] 王新俊.世界银行拟筹资10亿美元绘制非洲矿产地质图[EB/OL].(2014-03-24)[2016-03-05]. http://gb.cri.cn/42071/2014/03/24/6071s4476292.htm. Wang Xinjun.The World Bank Plans to Raise $1 Billion to Compiled Geological and Mineral Map of African[EB/OL].(2014-03-24)[2016-03-05]. http://gb.cri.cn/42071/2014/03/24/6071s4476292.htm.
[4] 任军平,王杰,刘晓阳,等.坦桑尼亚 Nzega 绿岩带 Golden Pride 金矿床研究进展[J].地质调查与研究,2013,36(1):47-53. Ren Junping,Wang Jie,Liu Xiaoyang,et al. New Progress on the Golden Pride Gold Deposit Research of Nzega Greenstone Belt in Tanzania[J].Geological Survey and Research,2013,36(1):47-53.
[5] 任军平,王杰,刘晓阳,等.非洲中南部卢弗里安弧Cu-Co矿床研究进展[J].地质科技情报, 2013,32(5):142-152. Ren Junping,Wang Jie,Liu Xiaoyang,et al. Research Progresses on the Cu-Co Deposits of Lufilian Area in the Mid-Southern Africa[J].Geological Science and Technology Information, 2013,32(5):142-152.
[6] 任军平,许康康,王杰,等.赞比亚东北部班韦乌卢地块地质特征及潜力矿产分析[J].矿床地质, 2014,33(增刊):1125-1126. Ren Junping,Xu Kangkang,Wang Jie,et al.Geological Characteristics and Mineral Potential Analysis of Bangweulu Block in Northeastern Zambia[J].Mineral Deposits, 2014,33(Sup.):1125-1126.
[7] 王杰,任军平,何胜飞,等.南非主要金矿集区研究现状及存在问题[J].地质论评,2014, 60(5):997-1008. Wang Jie,Ren Junping,He Shengfei,et al.Review of Studies on the Gold Deposit-Accumulated Area in South Africa[J].Geological Review, 2014, 60(5):997-1008.
[8] Haest M,Muchez P. Stratiform and Vein-Type Deposit in the Pan-African Orogen in Central and Southern Africa:Evidence for Multiphase Mineralization[J]. Geological Belgica,2011,14(1/2):23-44.
[9] Kampunzu A B. Geochemical Characterlsation, Provenance, Source and Depositional Environment of "Roches Argilo-Talqueuses"(RAT) and Mines Subgroups Sedimentary Rocks in the Neoproterozoic Katangan Belt(Congo):Lithostratigraphic Implications[J].Journal of African Earth Sciences,2005,42:119-133.
[10] Chartrand F M,Brown A C.Preliminarv Comparison of Diagenetic Stratiform Copper Mineralization from Redstone,NW Territories,Canada and Kamoto,Shaban Copperbelt,Zaire[J].Geological Society of London,1984,141: 291-297.
[11] Batumike M J,Kampunzu A B, Cailteux J H. Petrology and Geochemistry of the Neoproterozoic Nguha and Kuudeluugu Groups, Katangan Supergroup, Southeast Congo: Implications for Provenance,Paleoweathering and Geotectonic Settin[J].Journal of African Earth Sciences,2006, 44:97-115.
[12] Cailteux J L H, Kampunzu A B, Lerouge C.The Neoproterozoic Mwashva-Kansuki Sedimentary Rock Succession in the Central African Copperbelt,Its Cu-Co Mineralisation and Regional Correlations[J].Gondwana Research,2007,11:414-431.
[13] Cailteux J L H,Kampunzu A B,Lerouge C,et al. Genesis of Sediment-Hosted Stratiform Copper-Cobalt Deposits,Central African Copper Belts[J].Journal of African Earth Sciences,2005,42:134-158.
[14] Milesi J P,Toteu S F,Deschamps Y. An Overview of the Geology and Major Ore Deposits of Central Africa: Explanatory Note for the 1∶4 000 000 Map"Geology and Major Ore Deposits of Central Africa"[J].Journal of Africa Earth Sciences,2006,44: 571-591.
[15] Muchez P, Brems D, Clara E,et al. Evolution of Cu-Co Mineralizing Fluids at Nkana Mine,Central African Copperbelt, Zambia[J].Journal of African Earth Sciences,2010,58:457-474.
[16] 徐春宏,范良伍.刚果民主共和国卡尔维矿区快速锁定找矿靶区的成功要素[J].矿产勘查,2010,1(5): 488-494. Xu Chunhong,Fan Liangwu.The Successful Factorsto Quickly Locate Target Areas in Kalwe Ore Deposit,Katanga,Democratic Republic Congo[J].Mineral Exploration,2010,1(5): 488-494.
[17] Key R M,Liyungu A K,Njamu F M, et al.The Western Arm of the Lufilian Arc in NW Zambia and Its Potential for Copper Mineralization [J]. Journal of African Earth Sciences,2001,33:503-528.
[18] 贾伟洁,郭华,李迁.ASTER遥感影像与航磁梯度数据综合应用[J].吉林大学学报(地球科学版),2015,45(4):1237-1245. Jia Weijie,Guo Hua,Li Qian. Integrated Application of ASTER Remote Sensing Image and Aeromagnetic Gradient Data[J]. Journal of Jilin University(Earth Science Edition), 2015, 45(4):1237-1245.
[19] Dewaele S,Muchez Ph,Vest J,et al.Multiphaes Origin of the Cu-Co Ore Deposits in the Western Part of the Lulilian Fold and Thrust Belt,Katanga(Democratic Republic of Congo)[J]. Journal of African Earth Sciences,2006, 46(7): 455-469.
[20] 闫艳玲,李向前,姜玉平,等.中非铜带残坡积钴矿床地质特征及找矿方向[J].地质与勘探,2011,47(3):512-517. Yan Yanling,Li Xiangqian,Jiang Yuping,et al. Geological Characteristics and Prospecting Direction of the Elluvium-Deluvial Cobalt Deposits in the Central African Copper Belt[J].Geology and Exploration,2011,47(3):512-517.
[21] 赵英福.刚果(金)科卢韦齐铜矿地质特征及成矿机理浅析[J].矿产与地质,2011,25(3):203-207. Zhao Yingfu.Geological Characteristics and Mineralization Mechanism of the Kolwezi Copper Deposit,Congo[J].Mineral Resources and Geology,2011,25(3):203-207.
[22] 李向前,毛景文,闫艳玲,等.中非刚果(金)加丹加铜钴矿带主要矿化类型及特征[J].矿床地质,2009, 28(3):366-380. Li Xiangqian,Mao Jingwen,Yan Yanling, et al. Regional Geology and Characteristics of Ore Deposits in Katanga Copper-Cobalt Belt Within Congo (Kinshasa), Central Africa[J].Mineral Deposits,2009,28(3): 366-380.
[23] Fay I,Barton M D. Alteration and Ore Distribution in the Proterozoic Mines Series,Tenke-Fungurume Cu-Co District, Democratic Republic of Congo[J]. Mineralium Deposita,2012,47(5): 501-519.
[24] 任超,张昊,李文光.赞比亚谦比西铜矿矿床成因研究及其找矿意义[J].矿产勘查,2011,2(1):84-88. Ren Chao, Zhang Hao, Li Wenguang. The Genesis and Prospecting Implications of Chambishi Copper Deposit in Zambia [J]. Mineral Exploration, 2011, 2(1): 84-88.
[25] Stephen R,Martin R P,Matthew J C,et al.REE and Sr Isotope Characteristics of Carbonate Within the Cu-Co Mineralized Sedimentary Sequence of the Nchanga Mine,Zambian Copperbelt[J].Miner Deposita,2009,44:881-891.
[26] Webb G E,Kamber B S. Rare Earth Elements in Holocene Reefal Microbialites:A New Shallow Seawater Proxy[J]. Geochim Cosmochim Acta,2000,64:1557-1565.
[27] Ross R M G,Stephen R, Adrian J B.Origin of the Nchanga Copper-Cobalt Deposits of the Zambian Copperbelt[J]. Mineralium Deposita,2006,40:617-638.
[28] 李继宏,娄根有.刚果(金)加丹加省堪苏祁矿区堪苏祁1铜钴矿详查报告[R].北京:中国冶金地质总局第一地质勘查院,2008. Li Jihong,Lou Genyou. Kansuki 1Copper-Cobalt General Exploration Report in Kansuki Copper-Cobalt Deposit of Katanga Province,DRC[R].Beijing:The First Geological Institute of the China Metallurgical Geology Bureau,2008.
[29] Barra F,Broughton D,Ruiz J,et al.Multi-Stage Mineralization in the Zambian Copperbelt Based on Re-Os Isotope Constraints[C]//The Geological Society of America Abstracts with Program 36, Denver: The Geological Society of America, 2004:7-10.
[30] Porada H,Druschel G.Evidence for Participation of Microbial Mats in the Deposition of the Siliciclastic "Ore Formation" in the Copperbelt of Zambia[J].Journal of African Earth Sciences,2010,58:427-444.
[31] Armstrong R A,Robb L J,Masters S,et al. New U-Pb Age Constraints on the Katangan Sequence,Central African Copperbelt[J]. Journal of African Earth Sciences,1999, 28(4A):6-7.
[32] Rainaud C, Master S, Armstrong R A,et al. Monazite Dating and 40Ar-39Ar Thermochronology of Metamorphic Events in the Central African Copperbelt During the Pan-African Lufilian Orogeny[J]. Journal of African Earth Sciences,2005,42:183-199.
[33] Torrealday H L,Hitzman M W,Stein H J,et al.Re-Os and U-Pb Dating of the Vein-Hosted Mineralization at the Kansanshi Copper Deposit, Northern Zambia[J]. Economic Geology,2000, 95:1165-1170.
[34] Unrug R.Mineralization Controls and Source of Metals in the Lufilian Fold Belt,Shaba(Zaire),Zambia and Angola[J]. Economic Geology,1988,83:1247-1258.
[35] Cailteux J L H, Kampunzu A B H, Batumike M J. Lithostratigraphic Position and Petrographic Characteristics of R.A.T.("Roches Argilo-Talqueuses") Subgroup,Neoproterozoic Katangan Be1t(Congo)[J].Journal of African Earth Sciences,2005,42:82-94.
[36] Maier W D,Barnes S J,Chinyepi G,et al.The Composition of Magmatic Ni-Cu-(PGE) Sulfide Deposits in the Tati and Selebi-Phikwe Belts of Eastern Botswana[J].Miner Deposita,2008,43:37-60.
[37] Brown P J.Petrogenesis of Ni-Cu Ore Bodies, Their Host Rocks and Country Rocks at Selebi-Phikwe,Eastern Bostswana[D]. Southampton:University of Southampton, UK,1988:333.
[38] Barton J M, Klemd R,Zeh A.The Limpopo Belt: A Result of Archean to Proterozoic,Turkic-Type Orogenesis?[C]//Reimold WU,Gibson R L.Processes on the Early Earth.Geological Society of America Special Paper,2006,405:315-332.
[39] Lear P A.The Ore Mineralogy of the Phikwe and Selebi Nickel-Copper Deposits,Botswana[J].Geological Society of South Africa,1979,5:117-132.
[40] Gordon P S L.The Selebi-Pikwe Nickel-Copper Deposits,Botswana[J]. Geological Society of South Africa Special Publication, 1973(3):167-187.
[41] Wakefield J.The Structural and Metamorphic Evolution of the Phikwe Ni-Cu Sulfide Deposit,Selebi-Phikwe, Eastern Botswana[J]. Economic Geology,1976,71:988-1005.
[42] Wilson M.Igneous Petrogenesis[M]. London:Chapman and Hall, 1989:466.
[43] Jensen L S.A New Cation Plot for Classifying Subalkalic Volcanic Rocks[R]. Ontario:Ontario Geological Survey Miscellaneous Paper,1976: 1-22.
[44] Marco L F,Andrey B,Olivier R,et al. Multiple Sulfur and Iron Isotope Composition of Magmatic Ni-Cu-(PGE)[J].Economic Geology,2012,107:105-116.
[45] Bekker A,Barley M E,Fiorentini M,et al.Atmosp-heric Sulfur in Archean Komatiite-Hosted Nickel Deposits[J]. Science,2009, 326:1086-1089.
[46] Rouxel O,Shanks W C,Bach W,et al.Integrated Fe- and S-isotope Study of Seafloor Hydrothermal Vents at East Pacific Rise 9°-10° N[J].Chemical Geology, 2008, 252:214-227.
[47] Mc Court S,Kampunzu A B,Bagai Z,et al.The Crustal Architecture of Archean Terranes in Northeastern Botswana[J].South African Journal of Geology, 2004,107:147-158.
[48] Wright L. A Structural Cross Section Across the North Margin of the Limpopo Belt[D]. Leeds: University of Leeds, UK,1977.
[49] 汤中立,李文渊.金川铜镍硫化物(含铂)矿床成矿模式及地质对比[M].北京:地质出版社,1995. Tang Zhongli,Li Wenyuan.Metallogenic Model and Geological Correlation of Copper-Nickel Sulfide (Platinum Bearing) Deposit in Jinchuan[M].Beijing: Geological Publishing House, 1995.
[50] 翟裕生,邓军,宋鸿林,等.同生断层对层控超大型矿床的控制[J].中国科学:D辑,1998,28(3):214-218. Zhai Yusheng,Deng Jun,Song Honglin,et al.Control of Stratabound Giant Deposits by Syngenetic Fault[J]. Science in China: Series D,1998,28(3):214-218.
[51] Naldrett A J. KeyFactor in the Genesis of Noril'sk,Sudbury,Jinchuan,Voisey's Bay and Other World-Class Ni-Cu-PGE Deposits: Implications for Exploration[J].Australian Journal of Earth Science,1997,44:283-315.
[52] 李文渊.岩浆Cu-Ni-PGE硫化物矿床研究现状及发展趋势[J].西北地质,2007,40(2):1-28. Li Wenyuan. The Current Status and Prospect on Magmatic Ni-Cu-PGE Deposits [J]. Northwestern Geology, 2007, 40(2): 1-28.
[53] Majaule T,Hall R P.Geochemistry of Mafic and Ultramafic Igneous Rocks of the Matsitama Supracrustal Belt,Northeastern Botswana;Provenance Implications[J].South African Journal of Geology,1997,100(2):169-179.
[54] Michael Newbury,Howard Coates,Dino Titaro,et al. Technical Report on the Dukwe Copper Project and Matsitama Prospecting Licences Botswana, Africa[R].Toronto:A C A Howe International Limited, 2006: 1-9.
[55] Barton Jr J M, Blaine J L, Doig R, et al. The Geological Setting and Style of Copper Mineralization at the Bushman Group of Deposits,Northeastern Botswana[J].Journal of African Earth Sciences,1994,18(2): 87-97.
[56] Chacko T, Mayeda T K, Clayton R N, et al. Oxygen and Carbon Isotope Fractionations Between CO2 and Calcite[J]. Geochimica et Cosmochimica Acta,1991, 55(10): 2867-2882.
[57] Dunn S R,Valley J W. Calcite-Graphite Isotope The-rmometry: A Test for Polymetamorphism in Marble, Tudor Gabbro Aureole,Ontario,Canada[J]. Journal of Metamorphic Geology,1992,10(4): 487-501.
[58] Bagai Z, Armstrong R A,Kampunzu A B. U-Pb Single Zircon Geochronology of Granitoids in the Vumba Granite-Greenstone Terrain (NE Botswana): Implications for the Evolution of the Archaean Zimbabwe Craton[J]. Precambrian Research, 2000,118:149-168.
[59] Mc Court S,Armstrong R A. SHRIMP U-Pb Zircon Geochronology of Granites from the Central Zone,Limpopo Belt, Southern Africa: Implications for the Age of the Limpopo Orogeny[J]. South African Journal of Geology,1998,101:329-338.
[60] Coomer P G,Coward M P,Lintern B C. Stratigraphy,Structure and Geochronology of Ore Leads in the Matsitama Schist Belt of Northern Botswana[J]. Precambrian Research,1977,5:23-41.
[61] Groves D I, Ho S E, Rock N M S, et al. Archean Cratons,Diamond and Platinum: Evidence for Coupled Long-Lived Crust-Mantle Systems[J]. Geology,1987,15(9): 801-805.
[62] Treloar P J,Kramers J D. Metamorphism and Geochronology of Granulites and Migmatitic Granulites from the Magondi Mobile Belt,Zimbabwe[J]. Precambrian Research, 1989, 45(4): 277-289.
[63] 张伟波,聂凤军,曹毅,等.南非帕拉博鲁瓦超大型氧化铁型铜(金)矿床[J].矿床地质,2013,32(2):453-456. Zhang Weibo,Nie Fengjun,Cao Yi,et al.Palabora Gaint Iron-Oxide Type Copper(Gold) Deposit in South Africa[J].Mineral Deposits,2013,32(2):453-456.
[64] Hanekom H J,Van Staden C M V H,Smit P J,et al. The Geology of the Palabora Igneous Complex[R]. Pretoria:Deptment Mines of Geological Survey of South Africa(Memoir 54),1965.
[65] Frick C.The Phalaborwa Syenite Intrusions[J].Trans Geol Soc S Africa,1975,78:201-213.
[66] Fourier P J,De Jager D H.Phosphate in the Phala-borwa Complex[C]// Anhaeusser C, Maske S.Mineral Deposits of Southern Africa,Vols. I & Ⅱ. Johannesburg:Geological Society of South Africa, 1986:2239-2253.
[67] Groves D I,Vielreicher N M.The Phalabowra (Pala-bora) Carbonatite-Hosted Magnetite-Copper Sulfide Deposit,South Africa:An End-Member of the Iron-Oxide Copper-Gold-Rare Earth Element Deposit Groups?[J].Mineralium Deposita, 2001,36:189-194.
[68] Palabora Mining Company Limited Mine Geological and Mineralogical Staff.The Geology and Economic Deposits of Copper, Iron and Vermiculite in the Palabora Igneous Complex: A Brief Review[J].Economic Geology,1976,71:177-192.
[69] Richard T H Aldous.Copper-Rich Fluid Inclusions in Pyroxenes from the Guide Copper Mine, a Satellite Intrusion of the Palabora Igneous Complex,South Africa[J].Economic Geology,1986,81:143-155
[70] Heinrich E W.The PalaboraCarbonatitic Complex:A Unique Copper Deposit[J].Canad Mineral,1970,10:585-598.
[71] Hornig-Kjaarsgaard I. Rare Earth Elements Insöviticc Arbonatites and Their Mineral Phases[J]. Journalof Petrology,1998,39:2105-2121.
[72] Dawson J B,Hinton R W.Trace-Element Content and Partitioning in Calcite,Dolomite and Apatite in Carbonatite,Phalaborwa,South Africa[J]. Mineralogical Magazine, 2003, 67(5):921-930.
[73] Goff B H,Weinberg R,Groves D I, et al.The Giant Vergenoeg Fluorite Deposit in a Magnetite-Fluorite-Fayalite REE Pipe:A Hydrothermally-Altered Carbonatite-Related Pegmatoid?[J]. Mineralogy and Petrology,2004,80:173-199.
[74] Verwoerd W J.Update on Carbonatites of South Africa and Namibia[J].South African Journal of Geology,1993, 96: 75-95.
[75] Hedberg R M. Stratigraphy of the Ovamboland Basin, South West Africa[D]. Cape Tow:Chamber of Mines Precambrian Research Unit, University of Cape Town,1979:325.
[76] Coakley G J. The Mineral Industry of Namibia[C]// USGS,Minerals Yearbook,Area Reports,International: Ⅲ. Reston:U S Geological Survey,Reston, America,1997: DD1-DD7.
[77] Coakley G J.The Mineral Industry of Namibia[C]// USGS,Minerals Yearbook,Area Reports,International: Ⅲ. Reston:U S Geological Survey,Reston, America,2000: 1-23.
[78] Verran D. Genesis of the Khusib Springs Cu-Pb-Zn-(Ag) Deposit,Otavi Mountain Land, Namibia[D]. Cape Town:University of Cape Town,1996:30.
[79] Chetty D,Frimmel H E. The Role of Evaporites in the Genesis of Base Metal Sulfide Mineralization in the Northern Platform of the Pan-African Damara Belt, Namibia: Geochemical and Fluid Inclusion Evidence from Carbonate Wall Rock Alteration[J]. Mineralium Deposita,2000,35:364-376.
[80] Frank Melcher,Thomas Oberthür,Dieter Rammlmair.Geochemical and Mineralogical Distribution of Germanium in the Khusib Springs Cu-Zn-Pb-Ag Sulfide Deposit,Otavi Mountain Land,Namibia[J].Ore Geology Reviews,2006, 28:32-56.
[81] Gross C,Vollbrecht A.Cathodoluminescence Studies on Carbonates from the Otavi Mountain Land, Namibia[R]. Göttingen:GWZ Universität Göttingen,2003:49.
[82] Frimmel H E,Deane J G,Chadwick P J. Pan-African Tectonism and the Genesis of Base Metal Sulfide Deposits in the Northern Foreland of the Damara Orogen,Namibia[J].Society of Economic Geologists,1996,4:204-217.
[83] Misra K C.Understanding Mineral Deposits[M]. Dordrecht-Boston-London:Kluwer Academic Publishers, 2000:845.
[84] Allsopp H L, Welke H J,Hughes M J. Shortening the Odds in Exploration[J]. Nuclear Active,1981,24:8-12.
[85] Hughes M J. The Tsumeb Orebody,Namibia and Related Dolostone-Hosted Base Metal Deposits of Central Africa[D]. Johannesburg:University of the Witwatersrand,Johannesburg,South Africa,1987:448.
[86] Kamona A F, Léveque J,Friedrich G,et al. Lead Isotopes of the Carbonate-Hosted Kabwe,Tsumeb and Kipushi Pb-Zn-Cu Sulfide Deposits in Relation to Pan African Orogenesis in the Damaran-Lufilian Fold Belt of Central Africa[J]. Mineralium Deposita, 1999,34:273-283.
[87] 杨晓菲.博茨瓦纳发现铜镍钴矿床[J].中国金属通报,2009(16):10. Yang Xiaofei.The Discovery of Copper-Nickel-Cobalt Deposit in Botswana[J].China Metal Bulletin,2009(16):10.
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