“三联式”成矿预测理论在非传统矿产资源评价中的应用
|
摘要
铂族元素(PGE)因其贵重稀少和在分布上的极不均匀性(如仅南非就占了全球已探明储量的81%,俄罗斯占17%,美国、加拿大等国约占2%),以及在航空航天、汽车、电子、制药、珠宝等领域需求的不断增加,而造成了铂族资源严重紧缺和国际矿业市场上供求矛盾异常紧张,为此北美不得不开始从报废汽车尾气净化剂中回收铂金属。近年来,我国的铂族资源年消耗量高居全球第二,其中,我国首饰铂消费自2000年超过日本位居世界第一以后,已经连续多年保持这种迅猛增长的势头(如,2002年我国首饰铂消费达到150万盎司,而整个欧洲才17万盎司);而国内汽车工业的快速发展,又将进一步拉动汽车尾气净化催化剂铂消费这个巨大的市场,所以,就我国而言铂族资源形势更为严峻,虽有金川、金宝山等超大型含铂铜镍矿床,但铂族元素是呈铜镍的伴生组分产出,且品位较低。国内大量铂族金属需求尚依赖于进口,对国家安全产生影响(国际市场上铂的价格一涨再涨,2003年曾达到每盎司692美元,为23年来历史最高价,2003年~2004年曾经出现了中国人在国际市场上买不到铂的现象;国内自2002年以来已近20次上调首饰铂等的零售价,仅武汉市2006年刚开始的一个多月里首饰铂零售价就两次上涨,990Pt达到每克348元;一些珠宝行不得不用所谓的“钯金”代替“铂金”)。自然而然,铂族金属也就成为近年来世界矿产勘查的一个新热点,如2002年铂族金属投资为1.04亿美元,占世界非燃料固体矿产勘查投资的6.0%,比2001年增长52.9%;2003年铂族金属勘查投资继续升温,达到1.31亿美元,较2002年又增长26%。由于勘查经费和项目的增加,促使了一批具有工业意义铂族金属矿床被发现,如在南非Sheba's Ridge地区获得PGE金属储量557吨,Blue Ridge地区获得Au与PGE金属储量147吨;在澳大利亚Panton地区获得PGE金属储量140吨,Munni Munni地区获得PGE金属储量63.8吨;在芬兰Suhanko地区获得Au与PGE金属储量283吨;在我国云南金宝山铂钯矿床打到高品位矿体,Pt+Pd为2.88~6.97 g/T。总的说来,为缓解铂族资源紧缺所带来的压力,当前无非有两条路可走:一是加大境内外与基性超基性岩有关的铂族资源的风险勘探力度,二是开展非传统(非常规)类型的铂族资源(如黑色页岩型铂族矿床等)的评价研究。近二十年来,随着国际地质对比计划第254项“含金属黑色页岩”的开展,以及俄罗斯干谷、波兰蔡希斯坦等新类型铂族矿床的发现,黑色岩系中PGE、Au等贵金属研究一度成为热点,并取得了大量研究成果。此外,较廉价的C-OES等分析测试技术在铂族元素的应用正逐步成熟,为该领域科学研究与区域铂族资
Platinum Grope elements (PGE), is scarce, valuable, and uneven in the distribution (such as South Africa alone accounting for the global proven reserves 81%, Russia 17%, the United States and Canada about 2%), and in the aerospace, automobile, electronics, pharmaceuticals, jewelry, and other areas of increasing demands, which result in platinum mining with severe resource constraints and extraordinarily intense international market conflict between supply and demand delete, therefore, North America had to recycle platinum metals from tail gas purification of waste cars. In recent years, our country platinum resources consumption rates per year is the second in the world. (After exceeding that of Japan and being the top of the world in 2000), jewelry consumption in China which is beyond over Japan and the highest in the world 2000, has maintained the rapid growth (for example, in 2002, Chinese jewelry consumption reached 1.5 million oz, while the whole Europe was only 170,000 oz) for many years; Besides, the domestic auto industry's rapid development will spur automobile tail gas purification catalyst platinum consumption. So, as far as in China, platinum resources situation is even more grim. Though Jinchuan, and Jinbaoshan Cu-Ni-PGE deposits, platinum is a accompany element with copper nickel, and the grade is rather low. Domestic demand for platinum grope metals is still dependent on imports, which impact on national security (international market price of a platinum increased once and again, 692 U.S. dollars per ounce in 2003, the highest price for 23 years of history ,and in 2003 -2004 years it once occurred that in the international market Chinese could not purchase platinum; Since 2002 ,our country has increased the retail price of platinum jewelry nearly 20 times, just at the beginning of 2006, the retail price of platinum increases two times ,and the 990Pt reached 348 yuan per gram in Wuhan; Some jewelers had to use "palladium jewel" to replace the "platinum jewel"). Naturally, in recent years, platinum group metals mineral prospecting has become a new hot spot. For example, 2002 platinum group metals investment was 104 million U.S. dollars, accounting for 6.0% of the world's non-fuel mineral prospecting solid investment, increasing 52.9% compared with that in 2001; in 2003, it continued to invest in platinum family metals prospecting warm, reaching 131 million U. S. dollars, increasing 26% compared with that in 2002. A group of industrial significance platinum group metals deposits are found, for the survey for the project and outlay increased. Such as in South Africa Sheba's Ridge areas, PGE metal reserves is 557 tons, and Blue Ridge areas, Au and PGE metal reserves is 147 tons; In Panton areas, Australia, PGE metal reserves is 140 tons, and in Munni areas, PGE metal
Platinum Grope elements (PGE), is scarce, valuable, and uneven in the distribution (such as South Africa alone accounting for the global proven reserves 81%, Russia 17%, the United States and Canada about 2%), and in the aerospace, automobile, electronics, pharmaceuticals, jewelry, and other areas of increasing demands, which result in platinum mining with severe resource constraints and extraordinarily intense international market conflict between supply and demand delete, therefore, North America had to recycle platinum metals from tail gas purification of waste cars. In recent years, our country platinum resources consumption rates per year is the second in the world. (After exceeding that of Japan and being the top of the world in 2000), jewelry consumption in China which is beyond over Japan and the highest in the world 2000, has maintained the rapid growth (for example, in 2002, Chinese jewelry consumption reached 1.5 million oz, while the whole Europe was only 170,000 oz) for many years; Besides, the domestic auto industry's rapid development will spur automobile tail gas purification catalyst platinum consumption. So, as far as in China, platinum resources situation is even more grim. Though Jinchuan, and Jinbaoshan Cu-Ni-PGE deposits, platinum is a accompany element with copper nickel, and the grade is rather low. Domestic demand for platinum grope metals is still dependent on imports, which impact on national security (international market price of a platinum increased once and again, 692 U.S. dollars per ounce in 2003, the highest price for 23 years of history ,and in 2003 -2004 years it once occurred that in the international market Chinese could not purchase platinum; Since 2002 ,our country has increased the retail price of platinum jewelry nearly 20 times, just at the beginning of 2006, the retail price of platinum increases two times ,and the 990Pt reached 348 yuan per gram in Wuhan; Some jewelers had to use "palladium jewel" to replace the "platinum jewel"). Naturally, in recent years, platinum group metals mineral prospecting has become a new hot spot. For example, 2002 platinum group metals investment was 104 million U.S. dollars, accounting for 6.0% of the world's non-fuel mineral prospecting solid investment, increasing 52.9% compared with that in 2001; in 2003, it continued to invest in platinum family metals prospecting warm, reaching 131 million U. S. dollars, increasing 26% compared with that in 2002. A group of industrial significance platinum group metals deposits are found, for the survey for the project and outlay increased. Such as in South Africa Sheba's Ridge areas, PGE metal reserves is 557 tons, and Blue Ridge areas, Au and PGE metal reserves is 147 tons; In Panton areas, Australia, PGE metal reserves is 140 tons, and in Munni areas, PGE metal
引文
[1] A.J. Naldrett. 1992. A model for the Ni-Cu-PGE ores of the Noril'sk region and its application to other areas of flood basalt. Economic Geology, Vol.87: 1945-1962
[2] Ali, K., and Cheng, Q., 2005, Separation of Geochemical Anomalies from Backgrounds using Multifractal Power-Spectrum Analysis: a Case Study from Yunnan Province, South China, Proceedings of Annual Conference of the International Association for Mathematical Geology (IAMG'05), G1S and Spatial Analysis, Q. Cheng and G. Bonhma-Carter (eds.), v. 1, 464-469.
[3] Anchipov B.C. 1999. Mineral resources potential remote sensing exploration and assessment based on geo-dynamic-anomaly analysis. Proceeding of 4 international symposiumon" New Ideas in Earth Sciences". Moscow.
[4] Andy Wilde, Alaster Edwards, and Alexander Yakubchuk, 2003. Unconventional deposits of Pt and Pd: a review with implications for exploration. SEG Newsletter, n52: 1pp, 9-18
[5] Bonham-Carter, GR, Agterberg, F.P., and Weight, D.F., 1989. Weights of evidence modeling: A new approach to mapping mineral potential: In Statistical Applications in the Earth Science, Editors: Agterberg, F.P. and Bonham-Carter, GF., Geological Survey of Canada Paper 89-90,p.171-183
[6] Bonham-Carter GF, 1994. Geographic Information Systems for Geoscientist: Modelling with GIS.p. 317-337
[7] Brown A.C., 1997. World-class sediment-hosted stratiform copper deposits: characteristics, genetic concepts and metallotects. Australian Journal of Earth Sciences, Vol44: 317—328.
[8] Cheng, Q., 2004, A new model for quantifying anisotropic scalinvariance and for decomposition of mixing Patterns. Mathematical Geology, 36(3): 345-360
[9] Cheng Q., Zhang G., Lu C, Ko Connie, 2004. GIS spatial-temporal modeling of water systems in Greater Toronto, Canada. Journal of China University of Geosciences, 15, 275-282
[10] Cheng, Q., 2005, GIS based fractal/multifractal anomaly analysis for modelingand prediction of mineralization and mineral deposits, in "GIS for Geosciences", Jeff Harris and Denny Wright (eds.), Geological Association of Canada (in press)
[11] Cheng, Q., 2005, Multifractal modeling of hydrothermal mineralization: Sn deposit prediction in Gejiu mineral district, Yunnan, Southwestern China, Proceedings of Annual Conference of the International Association for Mathematical Geology (IAMG'05), GIS and Spatial Analysis, Q. Cheng and G. Bonhma-Carter (eds.), v. 1,446-451.
[12] Cheng, Q., 2005, Multiplicative cascade mineralization processes and singular distribution of mineral deposit associated geochemical anomalies, Proceedings of Annual Conference of the International Association for Mathematical Geology (IAMG'05), GIS and Spatial Analysis, Q. Cheng and G Bonhma-Carter (eds.), v. 1,297-302.
[13] Cheng, Q., Li, Q., 2002, A fractal concentration-area method for assigning a color palette for image representation. Computers & Geosciences, 28(4): 567~575
[14] D. Jay Miller, Robert R. Loucks, and Mohammad Ashraf. 1991. Platinum-group element mineralization in the Jijal layered ultramafic-mafic complex, Pakistani Himalayas. Economic Geology, Vol. 86: 1093~1102
[15] Demetrios G. Eliopoulos and Maria Economou-Eliopoulos. 1991. Platinum-Group Element and Gold Contents in the Skouries Porphyry Copper Deposit, Chalkidiki Peninsula, Northem Greece. Economic Geology, vol. 86, 740~749
[16] E. F. Stumpfl and M. Tarkian, 1976. Platinum genesis: new mineralogical evidence. Economic Geology, vol. 71, 1451~1460
[17] E. Van Der Flier-Keller. 1991. Platinum-Group Elements in Tulameen Coal, British olumbia, Canada. Economic Geology, vol. 86, 387~395
[18] Ge, Y., Cheng, Q., Zhang, S., 2005, Reduction of edge effects in spatial information extraction from geochemical data: a case study based on multifractal filtering technique, Computers & Geosciences, 31 (5): 545~554
[19] Gorelov D. A., 1982. Quantitative characteristics of geological anomalies in assessing ore capacity. Internal Geology Rew, N4: 457~465
[20] H Kucha and W Przybylowicz. 1999. Noble Metals in Orgnic Matter and Clay-Organic Matrces, Kupferschiefer, Poland. Economic Geology, V94: 1137~1162.
[21] H. L. O. Huyck, R. W. Chorey. 1991. Stratigraphic and petrographic comparison of the Creta and Kupferschiefer copper shale deposits. Mineralium Deposita, V26: 132~142
[22] Hulbert LJ Gregoire CD, and Paktunc D. 1992. Sedimentary nickel, zinc, and platinum-group-element mineralization in Devonian black shales at the Nick property, Yukon, Canada: a new deposit type. Explor Mineral Geology, No. 1 39~62
[23] J. S. Leventhal. 1991. Comparison of organic geochemistry and metal enrichment in two black shales: Cambrian Alum Shale of Sweden and Devonian Chattanooga Shale of United States. Mineralium Deposita, V26: 104~112
[24] Jan Pasava, Hladikova J, and Dobes P. 1996. Origin of Proterozoic metal-rich black shales from the Bohemian Massif, Czech Republic. Economic Geology, V91: 63~79
[25] Jan Pasava, Sarah-Jane, and Anna Vymazalova. 2003. The use of mantle normalization and metal ratios in the identification of the sources of platinum-group elements in various metal-rich black shales. Mineralium Deposita, 38: 775~783
[26] Jan Pasava. 1991. Comparison between the distribution of PGE in black shales from the Bohemian Massif (CSFR) and other black shale occurrences. Mineralium Deposita, V26: 99~103
[27] Jan Pasaya. 1996. A group of papers devoted to the metallogeny of black shales. Economic Geology, 91 (1): 1~2
[28] Jingwen Mao, Bemd Lehmann, Andao Du, et al. 2002. Re-Os Dating of Polymetallic Ni-Mo-PGE-Au Mineralization in Lower Cambrian Black Shales of South China and Its Geologic Significance. Economic Geology, 97: 1051~1061
[29] John C. Griffiths, 1978. Mineral resource assessment using the unit regional value concept. Mathematial Geology, 10(5): 441~472
[30] John C. Griffiths, A. D. Pilant, and Chester M. Smith, Jr., 1997. Quantitative estimates of the geology of large regions and their application to mineral-resource assessment. Nonrenewable Resources, 6(3): 157~236
[31] Jr, Coveney, R. M., Nansheng, C, 1991. Ni-Mo-PGE-Au-rich ores in Chinese black shales and speculations on possible analogues in the United States. Mineral Deposita, 26, 83~88.
[32] K. Loukola-Ruskeeniemi. 1991. Geochemical evidence for the hydrothermal origin of sulphur, base metals and gold in Proterozoic metamorphosed black shales, Kainuu and Outokumpu areas, Finland. Mineralium Deposita, V26: 152~167
[33] Kucha H, and Przybylowicz W. 1999. Noble metals in organic matter and clay-organic matrices, Kupferschiefer, Poland. Economic Geology, 94: 1137~1162
[34] Kucha H. 1982. Platinum-group metals in the Zechstein copper deposit, Poland. Economic Geology, 77: 1578~1591
[35] Li, Q., and Cheng, Q., 2005, A GIS-based W-A Fractal Model for Extracting Spatial Information from Geophysical and Geochemical Data, Proceedings of Annual Conference of the International Association for Mathematical Geology (IAMG'05), GIS and Spatial Analysis, Q. Cheng and G Bonhma-Carter (eds. ), v. 1., 470~474.
[36] Lindgren L. Chyu, 1982. The distribution of platinum in bituminous coal. Economic Geology, Vol. 77: 1592~1597
[37] M F Horan, J W Morgan, R I Grauch, et al. 1994. Rhenium and Osmium isotopes in black shales and Ni-Mo-PGE-rich sulfide layers, Yukon Territory, Canada, and Hunan and Guizhouprovince, China. Geochimica et Cosmochimica Acta, 58: 257~265
[38] M. Hattori, A. Fujiyama, T. D. Taylor, et al., 2000. The DNA sequence of human chromosome 21. Nature, v405: 311~319
[39] M. S. Quinby-Hunt, and P. Wilde. 1996. Chemical depositional environments of calcic marine black shales. Economic Geology, Vol. 91: 4~13
[40] McCallum M. E., Loucks R. R., Carlson R. R., et al., 1976. Platinum metals associated with hydrothermal copper ores of the New Rambler mine, Medicine Bow Mountains, Wyoming. Economic Geology, Vol. 71: 1429~1450
[41] Mihalik P., Jacobsen J. B. E., and Hiemstra S. A., 1974. Platinum-group minerals from a hydrothermal environment. Economic Geology, Vol. 69: 257~262
[42] Ponavic Michal, Pasava Jan, V Anna, et al. Impact of lower cambrian black shales and exploited Mo-Ni black shale-hosted deposits on the trace element composition of soils and crop plants in the Zunyi region, Guizhou province, south China. 32nd IGC.
[43] R. M. Coveney, Jr. C. Nansheng. 1991. Ni-Mo-PGE-Au-rich ores in Chinese black shales and speculations on possible analogues in the United States. Mineralium Deposita, v26, 83~88.
[44] Ross R. Large, Jocelyn McPhie, J. Bruce Gemmell, et al., 2001. The spectrum of ore deposit types, volcanic environments, alteration halos, and related exploration vectors in submarine volcanic successions: some examples from Australia. Economic Geology, Vol. 96: 913-938
[45] Scott M, Dimitrakopoulos R, Quantitative analysis of mineral resources for strategic planning: implications for Australian geological surveys. 2001, 10 (3): 159~177
[46] Shu DG, Conway Morris S, Zhang XL. 1996. A Pikaia-like Chordate from the Lower Cambrian of China. Nature, 384: 157~158
[47] Shu DG, Luo H, Conway Morris S, et al. 1999. Early Cambrian Vertebrates from South China. Nature, 402: 42~46
[48] Shu DG, Chen L, Han J, et al. 2001. The Early Cambrian Tunicate from South China. Nature, 411: 472~473
[49] Shu DG, Conway Morris S, Han J, et al. 2003. Head and Backbone of the Cambrian vertebrate Haikouichthys. Nature, 421: 526~529
[50] Shu DG, Conway Morris S, Zhang ZF, et al. 2003. A New Species of Yunnanozoans with Implications for Deuterostome Evolution. Science, 299: 1380~1384
[51] Vladimir N. Sazonov, Adriaan H. Van Herk, and Hugo De Boorder, 2001. Spatial and temporal distribution of gold deposits in the Urals. Economic Geology, Vol. 96: 685~703
[52] W. E. Stone, J. H. Crocket, and M. E. Fleet. 1993. Sulfide-poor platinum-group mineralization in komatiitic systems: Boston Creek flow, layered basaltic komatiite, Abitibi belt, Ontario. Economic Geology, Vol. 88: 817~836
[53] Wang, Z., Cheng, Q., Xia, Q., and Chen, Z., 2005, The P-A Fractal Model Charactering Microtexture Properties of Minerals, Proceedings of Annual Conference of the International Association for Mathematical Geology (IAMG'05), GIS and Spatial Analysis, Q. Cheng and G. Bonhma-Carter (eds.), v. 1, 317~322.
[54] Wedepohl K. H., 1995. The composition of the continental crust. Geochimica et Cosmochimica Acta, 59 (7): 1217~1232
[55] Xia Qinglin, Zhao Pengda, Zhang Shouting, and Sun Huashan. 2005. GIS Spatial-Temporal Model of Geological Anomaly: A Case for Cenozoic Geology in Northwestern Yunnan Province, China. Proceeding of 1AMG'05: GIS and Spatial Analysis. Vol. 2: 1111~1116
[56] Yang, Z. and Cheng, Q., 2005, Spatial Correlation Analysis: Case Study of Grades and Reserves of Lead (Pb) and Zinc (Zn) Deposits, South China, Proceedings of Annual Conference of the International Association for Mathematical Geology (IAMG'05), GIS and Spatial Analysis, Q. Cheng and G. Bonhma-Carter (eds. ), v. 1, 1059~1064.
[57] Zentilli M., and Graves M. C.. Carbon compounds and ore deposit models [abs. ]: IAGOD Quadrennial Symposium, 8th, 1990, A110~111
[58] Zhao Pengda, Chen Jianping, Chen Jianguo, et al., 2004. "Three-component" digital prospecting method: a new approach for mineral resources quantitative prediction and assessment. Journal of China University of Geosciences, 15(3), 245~252
[59] (古方译).1987.碳质—黑色页岩建造中的层控矿床.新疆地质科技,3:42~47
[60] Alexander Y.(陈永清译).1996.黑也页岩中的金和铂族元素.地质科学译丛,13 (4):94~5
[61] B.B.季斯特列尔等.(锁林译).1997.俄罗斯干谷金矿床中的铂族金属存在形式及其成因.国外地质科技,(7):37~47
[62] B.K.Hemepo B.东西伯利亚黑色页岩建造的综合铂—金—多金属矿及其远景.见:迈向21世纪的俄罗斯地质调查和矿产资源(第二卷).2001,中国地质调查局
[63] 加布利娜.1998.大型含铜砂页岩型矿床的形成特点.地质科技动态,(6):1~5.
[64] Sheldon, R. P., 1984. The Precambrian earth ice-ring model to account for changes in exogenic regimes from Proterozoic to Phanerozic eras,IGCE.第五届国际磷块岩讨论会文集2,北京:地质出版社
[65] 等.1994.沿海边区内生“黑色页岩”的形成条件.地质科学译丛,11(2):8~13.
[66] Turekian,Wedepohl.见:地球化学(南京大学地质学系编).北京:科学出版社,1979,p514
[67] 安延恺,李汉瑜.1989.勘探地层学与环境分析.北京:石油工业出版社
[68] 鲍振襄.1990.湘西北地区镍钼钒多金属矿床及金银矿化的地质特征与成矿条件.地质找矿论丛,(3):
[69] 鲍正襄,万榕江,包绝敏.2002.上扬子台区下寒武统黑色岩系中的钒矿床.云南地质,21(2):175~182
[70] 鲍正襄.1995.湖南西北部黑色岩系中的贵金属矿化及找矿.黄金地质,1(3):28~33
[71] 陈国达,彭省临,戴塔根,等.2004.云南铜多金属壳体大地构造与成矿学.长沙:中南大学出版社
[72] 陈国达.1960.地台活化说及其找矿意义.北京:地质出版社
[73] 陈好寿,冉崇英,等.1992.康滇地轴铜矿床同位素地球化学.北京:地质出版社
[74] 陈永清,夏庆霖,刘红光.2003.滇东Pt-Pd-Cu含矿建造地球化学特征及其含矿性分析.中国地质,22(9):704~707
[75] 陈永清,夏庆霖,刘红光.2003.黑色页岩建造中的贵金属矿产评价研究.地球物理学进展,18(2):261~268
[76] 陈智梁,陈世瑜.1987.扬子地块西缘地质构造演化.重庆:重庆出版社
[77] 成杭新,谢学锦,严光生,等.1998.中国泛滥平原沉积物中铂、钯丰度值及其地球化学省的初步研究.地球化学,27(2):101~107
[78] 池顺都,赵鹏大.2000.地质建造组合熵异常与找矿有利地段圈定.现代地质,14(4):423~428
[79] 池顺都,赵鹏大,刘粤湘.2001.研究矿床时间谱系的GIS途径.地球科学,26(2):180~184
[80] 邓晋福,莫宣学,赵海玲,等.1999中国东部燕山期岩石圈-软流圈系统大灾变与成矿环境.矿床地质,18(4):309~315
[81] 杜杨松.1999.壳幔成矿学初探.矿床地质,18(4):341~346
[82] 范德江,刘仲衡.1995.滇东非海相泥盆纪地层研究——滇东曲靖晚志留世—早泥盆世早期沉积环境.青岛海洋大学学报,25(2):239~246
[83] 范德廉,叶杰,杨瑞英,等.1987.扬子地台前寒武—寒武纪界线附近的地质事件与成矿作用.沉积学报,5(3):81~95
[84] 范德廉,张涛,叶杰等.2000.与黑色岩系有关的超大型矿床.见:中国超大型矿床(Ⅰ)(涂光炽等著).北京:科学出版社,204~218
[85] 冯本智.1989.论扬子准地台西缘前震旦纪基底及其成矿作用.地质学报,(4):338~348
[86] 冯本智,卢民杰,张治中.等.1990.康滇地区前震旦纪地质与成矿.北京:地质出版社
[87] 冯增昭,金振奎,杨玉卿,等.1994.滇黔桂地区二叠纪岩相古地理.北京:地质出版社
[88] 冯增昭,彭勇民,金振奎,等.2001.中国南方寒武纪和奥陶纪岩相古地理.北京:地质出版社
[89] 高振敏,罗泰义,李胜荣.1997.黑色岩系中贵金属富集层的成因:来自固定铵的佐证.地质地球化学,No.1:18~23
[90] 龚琳,何毅特,陈天佑,等.1996.云南东川元古宙裂谷型铜矿.北京:冶金工业出版社
[91] 国务院.2006.国务院关于加强地质工作的决定.国发(2006)4号
[92] 国土资源部.2004.我国重要矿产资源保障程度与开发利用.内部资料
[93] 国土资源部信息中心.2004.世界矿产资源年评(2002~2003).北京:地质出版社
[94] 国务院新闻办公室.2003.《中国的矿产资源政策》白皮书
[95] 何起祥.1978.沉积岩和沉积矿床.北京:地质出版社
[96] 何廷贵.1989.滇东渔户村组含磷岩系的划分与对比.矿物岩石,9(2):1~12
[97] 赫尔伯特LJ等.(沈承珩,刘道荣译).1991.铂族元素的地质环境.北京:地质出版社,101~107
[98] 黄汲清.1954.中国主要地质构造单位(英文-地质专报-甲种-20号,1945),(中译本).北京:地质出版社
[99] 江能人,王尊周,陈永光.1964.滇东地区寒武纪地层的探讨.地质学报,44(2):137~156
[100] 李昌年.1986.四川攀西裂谷带峨眉玄武岩的岩石学及其成因研究.地球科学,11(6):577~584
[101] 李复汉,覃嘉铭,中玉连,等.1988.康滇地区的前震旦系.重庆:重庆出版社
[102] 李红,王东坡,高福红,等.1994.吉林省中、新生代黑色页岩(油页岩)中某些金属元素富集特征.长春地质学院学报,24(3):291~297
[103] 李胜荣,高振敏,陈南生.1994.试论铂族元素地球化学示踪体系.矿物岩石地球化学通报,No.1:36~37
[104] 李胜荣,高振敏.1994.黑色岩系中铂族元素地质地球化学研究概况及其意义.地质地球化学,No.4:45~49
[105] 李胜荣,高振敏.1995.湘黔地区牛蹄塘组黑色岩系稀土特征——兼论海相热水沉积岩稀土模式.矿物学报,15(2):225~229
[106] 李胜荣,高振敏.1996.湘黔地区下寒武统黑色岩系热演化条件.地质地球化学,4:30~34
[107] 李胜荣,高振敏.2000.湘黔寒武系底部黑色岩系贵金属元素来源示踪.中国科学(D辑),30(2):169~174
[108] 李胜荣,肖启云,申俊峰,等.2002.贵州遵义下寒武统黑色岩系中贵金属的表生活动性初探.自然科学进展,12(6):612~616
[109] 李胜荣,肖启云,申俊峰,等.2002.湘黔下寒武统铂族元素来源与矿化年龄的Re-Os同位素制约.中国科学(D辑),32(7):568~575
[110] 梁有彬,李艺.1997.中国铂族元素矿床类型和地质特征.矿产与地质,11(3):145~151
[111] 梁有彬,朱文凤.1995.湘西北天门山地区镍钼矿床铂族元素富集特征及成因探讨.地质找矿论丛,10(1):55~65
[112] 林建英.1985.中国西南三省二叠纪玄武岩系的时空分布及其地质特征.科学通报,12:929~932
[113] 刘宝珺、许效松、潘杏南,等.1993.中国南方古大陆沉积地壳演化与成矿.北京:科学出版社
[114] 刘本培,蔡运龙,等.2000.地球科学导论.北京,高等教育出版社
[115] 刘秉光.2002.中国PGE矿床类型分析.地质与勘探,38(4):1~7
[116] 刘朝基,曾绪伟,金久堂,等.1988.康滇地区基性超基性岩.重庆,重庆出版社,227~231
[117] 刘家铎,张成江,刘显凡,等.2004.扬子地台西南缘成矿规律及找矿方向.北京:地质出版社,130~185
[118] 刘玉强,龚羽飞.2004.我国主要矿产资源及矿产品供需形势分析与对策建议.地质与矿产,18(3):294-296
[119] 卢家烂,庄汉平,傅家谟.1999.湖北兴山白果园黑色页岩型银钒矿床中银钒赋存状态研究.地球化学,28(3):222~230
[120] 罗惠麟,蒋志文,何廷贵.1982.川滇地区震旦系—寒武系界线.地质科学,2:215~219
[121] 罗惠麟,蒋志文,唐良栋.1994.中国下寒武统建阶层型剖面.昆明:云南科技出版社
[122] 罗惠麟,蒋志文,武希彻,等.1982.云南东部震旦系—寒武系界线.昆明:云南人民出版社
[123] 罗惠麟,蒋志文,邢裕盛,等.1984.中国云南晋宁梅树村震旦系—寒武系界线层型剖面.昆明:云南人民出版社
[124] 罗惠麟,蒋志文,徐重九,等.1980.云南晋宁梅树村、王家湾震旦系—寒武系界线研究.地质学报,54(2):95~112
[125] 罗惠麟,武希彻,欧阳麟.1991.云南东部震旦系—寒武系界线地层的相变与横向对比.岩相古地理,(4):27~35
[126] 罗君烈.1995.云南铂、铜镍、铬矿的成矿床模式.云南地质,14(4):311~318
[127] 骆耀南.1985.中国攀枝花—西昌古裂谷带,中国攀西裂谷文集1.北京:地质出版社
[128] 钱逸,朱茂炎,何廷贵,等.1996.再论滇东前寒武系与寒武系界线剖面.微体 古生物学报,13(3):225~240
[129] 沈发奎.1989.攀西裂谷火山岩系某些成因特点的地球化学证据.地球化学,2:158~165
[130] 孙晓明,王敏,薛婷,等.2003.华南下寒武统黑色岩系铂多金属矿中黄铁矿流体包裹体的Hc-Ar同位素体系.高效地质学报,9(4):661~666
[131] 唐朝京,雷菁.2003.信息论与编码基础.长沙:国防科技大学出版社
[132] 唐良栋.1994.云南东部早寒武世沉秘相古地理.云南地质,13(3):240-252
[133] 陶奎元,毛建仁,刑光祸,等.1999.中国东部燕山期火山-岩浆大爆发.矿床地质,18(4):316~322
[134] 涂光炽.1999.贵金属找矿中若干问题的讨论.论当代矿产资源勘查评价的理论与方法,陈毓川主编.北京:地震出版社,186~191
[135] 万天丰.2004.中国大地构造学纲要.北京:地质出版社
[136] 王宝禄,李文昌.2001.西南三江(中南段)褶皱带及邻区深部地质构造一些问题探讨.见:应用物探资料研究重点成矿区带的区域构造和成矿构造文集(孙文珂,黄崇轲,丁鹏飞等著).北京:地质出版社,118~129
[137] 王敏,孙晓明,马名扬.2004.华南黑色岩系铂多金属成矿流体地球化学及其矿床成因意义.中山大学学报(自然科学版),43(5):98~102
[138] 王世称.2005.大型、超大型矿床定量预测.全国数学地质、矿产资源评价及GIS应用研讨会,湖北,武汉
[139] 王学求.1998.深穿透勘查地球化学.物探与化探,22(3):166~169
[140] 王学求.2004.新类型难识别矿地球化学勘查.物探与化探,28(3):202~205
[141] 王砚耕,王尚彦.2003.峨眉山大火成岩省与玄武岩铜矿——以贵州二叠纪玄武岩分布区为例.贵州地质,26(1):5~10
[142] 王祖英,江能人,谭雪春,袁品泉等.1995.云南岩相古地理图集.昆明:云南科技出版社
[143] 吴朝东,陈其英,杨承运.1999.湘西黑色岩系沉积演化与含矿序列.沉积学报,17(2):168~175
[144] 吴朝东,储著银.2001.黑色页岩微量元素形态分析及地质意义.矿物岩石地球化学通报,20(1):14~20
[145] 吴朝东,申延平,侯泉林.2001.湘西黑色岩系铂族元素地球化学特征及富集因素.自然科学进展,11(5):507~513
[146] 吴朝东,杨承运,陈其英.1999.湘西黑色岩系地球化学特征和成因意义.岩石矿物学杂志,18(1):26~39
[147] 吴朝东.2000.湘西震旦—寒武纪交替时期古海洋环境的恢复.地学前缘,7(增刊):45~57
[148] 吴上龙,陈元坤,李丽辉,等.1990.云南省区域物化探资料综合研究报告(内部资料).134-140
[149] 吴应林,朱忠发,王吉礼,等.1989.上扬子台地早、中三叠世岩相古地理及沉积矿产的环境控制.重庆:重庆出版社
[150] 夏庆霖,赵鹏大.2002.致矿地质异常解析.2002国际数学地质研讨会论文集, 31~32
[151] 夏庆霖,陈永清,赵鹏大.2003.滇东Pt-Pd地球化学填图及其异常评价.地质通报,22(9):704~707
[152] 夏庆霖,张寿庭,赵鹏大,等.2003.幂律度与成矿预测.成都理工大学学报(自然科学版),30(5):453~456
[153] 谢学锦.1979.区域化探.北京:地质出版社,118~124
[154] 谢学锦.1997.矿产勘查的新战略.物探与化探,21(6):402~410
[155] 谢学锦,邵跃,王学求.1999.走向211世纪矿产勘查地球化学.北京:地质出版社
[156] 谢学锦.2001.进入21世纪的勘查地球化学.中国地质,28(4):11~18
[157] 谢学锦,王学求.2003.深穿透地球化学新进展.地学前缘,10(1):225~238
[158] 邢树文,孙景贵,刘洪文.2002.高碳黑色页岩型铂族元素矿床的成矿性探讨.地质与勘探,38(6):17~21
[159] 熊兴武,侯蜀光,薛顺荣.1995.滇中昆阳群因民组地层学与岩相古地理.武汉:中国地质大学出版社
[160] 杨剑,易发成,侯兰杰.2004.黔北黑色岩系的岩石地球化学特征和成因.矿物学报,24(3):285~289
[161] 杨剑,易发成,刘涛,等.2005.黔北黑色岩系稀土地球化学特征及成因意义.地质科学,40(1):84~94
[162] 杨荆舟,罗君烈,赵准.1998.云南矿床区域成矿模式.云南地质,增刊:1~134
[163] 杨勤生.2001.云南东部及邻区黑色岩系内的矿床(化)特征与找矿设想.云南地质,20(1):59~72
[164] 杨瑞瑛,黄忠祥,李继亮.1985.攀西裂谷火成岩组合的微量元素地球化学.中国科学B,9:844~854
[165] 杨星,杨宗镜.1991.铂族元素成矿模式新发展与找矿设想.当代地质科学技术进展,7~10
[166] 叶杰,范德廉.2000.黑色岩系型矿床的形成作用及其在我国的产出特征.矿物岩石地球化学通报,19(2):95~102
[167] 叶天竺,朱裕生,夏庆霖,等.2004.固体矿产预测评价方法技术.北京:中国大地出版社
[168] 易发成,杨剑,侯兰杰,等.2004。黔北黑色岩系的铂族元素地球化学特征及成因探讨.地质科学,39(3):367~374
[169] 于炳松,H.Dong,E.Widom,等.2004.塔里木盆地北部下寒武统底部黑色页岩Os-Re和Nd同位素特征及其与样子地台的对比.中国科学(D辑),34(增刊Ⅰ):83~88
[170] 于炳松,陈建强,李兴武,等.2002.塔里木盆地下寒武统底部黑色页岩地球化学特征及其岩石圈演化意义.中国科学(D辑),32(5):374~382
[171] 於崇文.2003.地质系统的复杂性.北京:地质出版社
[172] 袁学诚.1989.论康滇地轴的深部构造.地质学报,(1):1~13
[173] 云南省地质局第二区域地质调查大队.1980.1:20万区域地质调查报告——东 川幅(矿产部分).46~50
[174] 云南省地质矿产局.1990.云南省区域地质志.北京:地质出版社
[175] 翟裕生,邓军,李晓波,等.1999.区域成矿学.北京:地质出版社
[176] 翟裕生,邓军,汤中立,等.2002.古陆边缘成矿系统.北京:地质出版社
[177] 翟裕生,彭润民,王建平,等.2003.成矿系列的结构模型研究.高校地质学报,9(4):510~519
[178] 翟裕生,王建平,邓军,等.2002.成矿系统与矿化网络研究.矿床地质,21(2):106~112
[179] 张爱云,伍大茂,郭丽娜,等.1987.海相黑色页岩建造地球化学与成矿意义.北京:科学出版社
[180] 张春晖译.1997.黑色板岩金矿中铂族元素的存在形式.贵金属地质,6(1):77~80
[181] 张光弟,李九玲,熊群尧,等.2002.贵州遵义黑色页岩铂族金属富集特点及富集模式.矿床地质,21(4):377~386
[182] 张光弟,毛景文,熊群尧.2001.中国铂族金属资源现状与前景.地球学报,22(2):107~110
[183] 张光前,李继英.1991.定量岩石地层学.武汉:中国地质大学出版社
[184] 张洪,陈方伦.1996.铂组元素分析方法、矿床地球化学及地球化学勘查.北京:地质出版社
[185] 张俊明,李国祥,周传明.1997.滇东下寒武统含磷岩系底部火山喷发事件沉积及其意义.地层学杂志,21(2):91~155
[186] 张乾,董振生,战新志.1995.鄂西白果园黑色页岩型银钒矿床地球化学特征.矿物学报,15(2):185~191
[187] 张翼飞.1993.云南省区域矿产总结.5~20
[188] 张振飞,夏庆霖.2005.成矿环境空间结构的模糊建模.地球科学,30(1):109~113
[189] 赵鹏大.1982.试论地质体的数学特征.地球科学,7(1):145~155
[190] 赵鹏大,孟宪国.1993.地质异常与矿产预测.地球科学,18(1):39~47
[191] 赵鹏大,陈建平,张寿庭.2003.“三联式”成矿预测新进展.地学前缘,10(2):455~463
[192] 赵鹏大.2001.地球科学的新使命——认知和发现非传统矿产资源.地球物理学进展,16(4):127~132
[193] 赵鹏大,陈建平,陈建国.2001.成矿多样性与矿床谱系.地球科学,26(2):111~117
[194] 赵鹏大,陈建甲.2000.非传统矿产资源体系及其关键科学问题.地球科学进展,15(3):251~255
[195] 赵鹏大,陈永清,刘吉平,等.1999.地质异常成矿预测理论与实践.武汉:中国地质大学出版社
[196] 赵鹏大,池顺都,陈永清.1996.查明地质异常:成矿预测的基础.高校地质学报,2(4):361~373
[197] 赵鹏大,池顺都.1991.初论地质异常.地球科学——中国地质大学学报,16(3):241~248
[198] 赵鹏大,王京贵,饶明辉等.1995.中国地质异常.地球科学——中国地质大学 学报,20(2):117~127
[199] 赵鹏大等.2003.非传统矿产资源概论.北京:地质出版社
[200] 郑大中.1997.铂族元素迁移富集机理的新探.四川地质学报,17(2):148-156
[201] 郑玉清.2001.云南省东川—曲靖地区地质异常与铂钯成矿预测.中国地质大学:工程硕士学位论文
[202] 中国科学院地质研究所.1959.中国大地构造纲要.北京:科学出版社
[203] 朱炳泉,常向阳,邱华宁,等.2000.扬子地台西南缘滇中元古宇特征及赋存超大型矿床的可能性.见:中国超大型矿床(Ⅰ)(涂光炽等著).北京:科学出版社,95~116
[204] 朱笑青,王中刚,陈南生.1996.镍钼在黑色岩系中富集成因的实验研究.大地构造与成矿学,20(4):368~374
[205] 庄汉平,卢家烂,傅家谟,等.1998.湖北兴山白果园黑色页岩型银钒矿床改造成矿作用的证据.科学通报,1328~1332
[2] Ali, K., and Cheng, Q., 2005, Separation of Geochemical Anomalies from Backgrounds using Multifractal Power-Spectrum Analysis: a Case Study from Yunnan Province, South China, Proceedings of Annual Conference of the International Association for Mathematical Geology (IAMG'05), G1S and Spatial Analysis, Q. Cheng and G. Bonhma-Carter (eds.), v. 1, 464-469.
[3] Anchipov B.C. 1999. Mineral resources potential remote sensing exploration and assessment based on geo-dynamic-anomaly analysis. Proceeding of 4 international symposiumon" New Ideas in Earth Sciences". Moscow.
[4] Andy Wilde, Alaster Edwards, and Alexander Yakubchuk, 2003. Unconventional deposits of Pt and Pd: a review with implications for exploration. SEG Newsletter, n52: 1pp, 9-18
[5] Bonham-Carter, GR, Agterberg, F.P., and Weight, D.F., 1989. Weights of evidence modeling: A new approach to mapping mineral potential: In Statistical Applications in the Earth Science, Editors: Agterberg, F.P. and Bonham-Carter, GF., Geological Survey of Canada Paper 89-90,p.171-183
[6] Bonham-Carter GF, 1994. Geographic Information Systems for Geoscientist: Modelling with GIS.p. 317-337
[7] Brown A.C., 1997. World-class sediment-hosted stratiform copper deposits: characteristics, genetic concepts and metallotects. Australian Journal of Earth Sciences, Vol44: 317—328.
[8] Cheng, Q., 2004, A new model for quantifying anisotropic scalinvariance and for decomposition of mixing Patterns. Mathematical Geology, 36(3): 345-360
[9] Cheng Q., Zhang G., Lu C, Ko Connie, 2004. GIS spatial-temporal modeling of water systems in Greater Toronto, Canada. Journal of China University of Geosciences, 15, 275-282
[10] Cheng, Q., 2005, GIS based fractal/multifractal anomaly analysis for modelingand prediction of mineralization and mineral deposits, in "GIS for Geosciences", Jeff Harris and Denny Wright (eds.), Geological Association of Canada (in press)
[11] Cheng, Q., 2005, Multifractal modeling of hydrothermal mineralization: Sn deposit prediction in Gejiu mineral district, Yunnan, Southwestern China, Proceedings of Annual Conference of the International Association for Mathematical Geology (IAMG'05), GIS and Spatial Analysis, Q. Cheng and G. Bonhma-Carter (eds.), v. 1,446-451.
[12] Cheng, Q., 2005, Multiplicative cascade mineralization processes and singular distribution of mineral deposit associated geochemical anomalies, Proceedings of Annual Conference of the International Association for Mathematical Geology (IAMG'05), GIS and Spatial Analysis, Q. Cheng and G Bonhma-Carter (eds.), v. 1,297-302.
[13] Cheng, Q., Li, Q., 2002, A fractal concentration-area method for assigning a color palette for image representation. Computers & Geosciences, 28(4): 567~575
[14] D. Jay Miller, Robert R. Loucks, and Mohammad Ashraf. 1991. Platinum-group element mineralization in the Jijal layered ultramafic-mafic complex, Pakistani Himalayas. Economic Geology, Vol. 86: 1093~1102
[15] Demetrios G. Eliopoulos and Maria Economou-Eliopoulos. 1991. Platinum-Group Element and Gold Contents in the Skouries Porphyry Copper Deposit, Chalkidiki Peninsula, Northem Greece. Economic Geology, vol. 86, 740~749
[16] E. F. Stumpfl and M. Tarkian, 1976. Platinum genesis: new mineralogical evidence. Economic Geology, vol. 71, 1451~1460
[17] E. Van Der Flier-Keller. 1991. Platinum-Group Elements in Tulameen Coal, British olumbia, Canada. Economic Geology, vol. 86, 387~395
[18] Ge, Y., Cheng, Q., Zhang, S., 2005, Reduction of edge effects in spatial information extraction from geochemical data: a case study based on multifractal filtering technique, Computers & Geosciences, 31 (5): 545~554
[19] Gorelov D. A., 1982. Quantitative characteristics of geological anomalies in assessing ore capacity. Internal Geology Rew, N4: 457~465
[20] H Kucha and W Przybylowicz. 1999. Noble Metals in Orgnic Matter and Clay-Organic Matrces, Kupferschiefer, Poland. Economic Geology, V94: 1137~1162.
[21] H. L. O. Huyck, R. W. Chorey. 1991. Stratigraphic and petrographic comparison of the Creta and Kupferschiefer copper shale deposits. Mineralium Deposita, V26: 132~142
[22] Hulbert LJ Gregoire CD, and Paktunc D. 1992. Sedimentary nickel, zinc, and platinum-group-element mineralization in Devonian black shales at the Nick property, Yukon, Canada: a new deposit type. Explor Mineral Geology, No. 1 39~62
[23] J. S. Leventhal. 1991. Comparison of organic geochemistry and metal enrichment in two black shales: Cambrian Alum Shale of Sweden and Devonian Chattanooga Shale of United States. Mineralium Deposita, V26: 104~112
[24] Jan Pasava, Hladikova J, and Dobes P. 1996. Origin of Proterozoic metal-rich black shales from the Bohemian Massif, Czech Republic. Economic Geology, V91: 63~79
[25] Jan Pasava, Sarah-Jane, and Anna Vymazalova. 2003. The use of mantle normalization and metal ratios in the identification of the sources of platinum-group elements in various metal-rich black shales. Mineralium Deposita, 38: 775~783
[26] Jan Pasava. 1991. Comparison between the distribution of PGE in black shales from the Bohemian Massif (CSFR) and other black shale occurrences. Mineralium Deposita, V26: 99~103
[27] Jan Pasaya. 1996. A group of papers devoted to the metallogeny of black shales. Economic Geology, 91 (1): 1~2
[28] Jingwen Mao, Bemd Lehmann, Andao Du, et al. 2002. Re-Os Dating of Polymetallic Ni-Mo-PGE-Au Mineralization in Lower Cambrian Black Shales of South China and Its Geologic Significance. Economic Geology, 97: 1051~1061
[29] John C. Griffiths, 1978. Mineral resource assessment using the unit regional value concept. Mathematial Geology, 10(5): 441~472
[30] John C. Griffiths, A. D. Pilant, and Chester M. Smith, Jr., 1997. Quantitative estimates of the geology of large regions and their application to mineral-resource assessment. Nonrenewable Resources, 6(3): 157~236
[31] Jr, Coveney, R. M., Nansheng, C, 1991. Ni-Mo-PGE-Au-rich ores in Chinese black shales and speculations on possible analogues in the United States. Mineral Deposita, 26, 83~88.
[32] K. Loukola-Ruskeeniemi. 1991. Geochemical evidence for the hydrothermal origin of sulphur, base metals and gold in Proterozoic metamorphosed black shales, Kainuu and Outokumpu areas, Finland. Mineralium Deposita, V26: 152~167
[33] Kucha H, and Przybylowicz W. 1999. Noble metals in organic matter and clay-organic matrices, Kupferschiefer, Poland. Economic Geology, 94: 1137~1162
[34] Kucha H. 1982. Platinum-group metals in the Zechstein copper deposit, Poland. Economic Geology, 77: 1578~1591
[35] Li, Q., and Cheng, Q., 2005, A GIS-based W-A Fractal Model for Extracting Spatial Information from Geophysical and Geochemical Data, Proceedings of Annual Conference of the International Association for Mathematical Geology (IAMG'05), GIS and Spatial Analysis, Q. Cheng and G Bonhma-Carter (eds. ), v. 1., 470~474.
[36] Lindgren L. Chyu, 1982. The distribution of platinum in bituminous coal. Economic Geology, Vol. 77: 1592~1597
[37] M F Horan, J W Morgan, R I Grauch, et al. 1994. Rhenium and Osmium isotopes in black shales and Ni-Mo-PGE-rich sulfide layers, Yukon Territory, Canada, and Hunan and Guizhouprovince, China. Geochimica et Cosmochimica Acta, 58: 257~265
[38] M. Hattori, A. Fujiyama, T. D. Taylor, et al., 2000. The DNA sequence of human chromosome 21. Nature, v405: 311~319
[39] M. S. Quinby-Hunt, and P. Wilde. 1996. Chemical depositional environments of calcic marine black shales. Economic Geology, Vol. 91: 4~13
[40] McCallum M. E., Loucks R. R., Carlson R. R., et al., 1976. Platinum metals associated with hydrothermal copper ores of the New Rambler mine, Medicine Bow Mountains, Wyoming. Economic Geology, Vol. 71: 1429~1450
[41] Mihalik P., Jacobsen J. B. E., and Hiemstra S. A., 1974. Platinum-group minerals from a hydrothermal environment. Economic Geology, Vol. 69: 257~262
[42] Ponavic Michal, Pasava Jan, V Anna, et al. Impact of lower cambrian black shales and exploited Mo-Ni black shale-hosted deposits on the trace element composition of soils and crop plants in the Zunyi region, Guizhou province, south China. 32nd IGC.
[43] R. M. Coveney, Jr. C. Nansheng. 1991. Ni-Mo-PGE-Au-rich ores in Chinese black shales and speculations on possible analogues in the United States. Mineralium Deposita, v26, 83~88.
[44] Ross R. Large, Jocelyn McPhie, J. Bruce Gemmell, et al., 2001. The spectrum of ore deposit types, volcanic environments, alteration halos, and related exploration vectors in submarine volcanic successions: some examples from Australia. Economic Geology, Vol. 96: 913-938
[45] Scott M, Dimitrakopoulos R, Quantitative analysis of mineral resources for strategic planning: implications for Australian geological surveys. 2001, 10 (3): 159~177
[46] Shu DG, Conway Morris S, Zhang XL. 1996. A Pikaia-like Chordate from the Lower Cambrian of China. Nature, 384: 157~158
[47] Shu DG, Luo H, Conway Morris S, et al. 1999. Early Cambrian Vertebrates from South China. Nature, 402: 42~46
[48] Shu DG, Chen L, Han J, et al. 2001. The Early Cambrian Tunicate from South China. Nature, 411: 472~473
[49] Shu DG, Conway Morris S, Han J, et al. 2003. Head and Backbone of the Cambrian vertebrate Haikouichthys. Nature, 421: 526~529
[50] Shu DG, Conway Morris S, Zhang ZF, et al. 2003. A New Species of Yunnanozoans with Implications for Deuterostome Evolution. Science, 299: 1380~1384
[51] Vladimir N. Sazonov, Adriaan H. Van Herk, and Hugo De Boorder, 2001. Spatial and temporal distribution of gold deposits in the Urals. Economic Geology, Vol. 96: 685~703
[52] W. E. Stone, J. H. Crocket, and M. E. Fleet. 1993. Sulfide-poor platinum-group mineralization in komatiitic systems: Boston Creek flow, layered basaltic komatiite, Abitibi belt, Ontario. Economic Geology, Vol. 88: 817~836
[53] Wang, Z., Cheng, Q., Xia, Q., and Chen, Z., 2005, The P-A Fractal Model Charactering Microtexture Properties of Minerals, Proceedings of Annual Conference of the International Association for Mathematical Geology (IAMG'05), GIS and Spatial Analysis, Q. Cheng and G. Bonhma-Carter (eds.), v. 1, 317~322.
[54] Wedepohl K. H., 1995. The composition of the continental crust. Geochimica et Cosmochimica Acta, 59 (7): 1217~1232
[55] Xia Qinglin, Zhao Pengda, Zhang Shouting, and Sun Huashan. 2005. GIS Spatial-Temporal Model of Geological Anomaly: A Case for Cenozoic Geology in Northwestern Yunnan Province, China. Proceeding of 1AMG'05: GIS and Spatial Analysis. Vol. 2: 1111~1116
[56] Yang, Z. and Cheng, Q., 2005, Spatial Correlation Analysis: Case Study of Grades and Reserves of Lead (Pb) and Zinc (Zn) Deposits, South China, Proceedings of Annual Conference of the International Association for Mathematical Geology (IAMG'05), GIS and Spatial Analysis, Q. Cheng and G. Bonhma-Carter (eds. ), v. 1, 1059~1064.
[57] Zentilli M., and Graves M. C.. Carbon compounds and ore deposit models [abs. ]: IAGOD Quadrennial Symposium, 8th, 1990, A110~111
[58] Zhao Pengda, Chen Jianping, Chen Jianguo, et al., 2004. "Three-component" digital prospecting method: a new approach for mineral resources quantitative prediction and assessment. Journal of China University of Geosciences, 15(3), 245~252
[59] (古方译).1987.碳质—黑色页岩建造中的层控矿床.新疆地质科技,3:42~47
[60] Alexander Y.(陈永清译).1996.黑也页岩中的金和铂族元素.地质科学译丛,13 (4):94~5
[61] B.B.季斯特列尔等.(锁林译).1997.俄罗斯干谷金矿床中的铂族金属存在形式及其成因.国外地质科技,(7):37~47
[62] B.K.Hemepo B.东西伯利亚黑色页岩建造的综合铂—金—多金属矿及其远景.见:迈向21世纪的俄罗斯地质调查和矿产资源(第二卷).2001,中国地质调查局
[63] 加布利娜.1998.大型含铜砂页岩型矿床的形成特点.地质科技动态,(6):1~5.
[64] Sheldon, R. P., 1984. The Precambrian earth ice-ring model to account for changes in exogenic regimes from Proterozoic to Phanerozic eras,IGCE.第五届国际磷块岩讨论会文集2,北京:地质出版社
[65] 等.1994.沿海边区内生“黑色页岩”的形成条件.地质科学译丛,11(2):8~13.
[66] Turekian,Wedepohl.见:地球化学(南京大学地质学系编).北京:科学出版社,1979,p514
[67] 安延恺,李汉瑜.1989.勘探地层学与环境分析.北京:石油工业出版社
[68] 鲍振襄.1990.湘西北地区镍钼钒多金属矿床及金银矿化的地质特征与成矿条件.地质找矿论丛,(3):
[69] 鲍正襄,万榕江,包绝敏.2002.上扬子台区下寒武统黑色岩系中的钒矿床.云南地质,21(2):175~182
[70] 鲍正襄.1995.湖南西北部黑色岩系中的贵金属矿化及找矿.黄金地质,1(3):28~33
[71] 陈国达,彭省临,戴塔根,等.2004.云南铜多金属壳体大地构造与成矿学.长沙:中南大学出版社
[72] 陈国达.1960.地台活化说及其找矿意义.北京:地质出版社
[73] 陈好寿,冉崇英,等.1992.康滇地轴铜矿床同位素地球化学.北京:地质出版社
[74] 陈永清,夏庆霖,刘红光.2003.滇东Pt-Pd-Cu含矿建造地球化学特征及其含矿性分析.中国地质,22(9):704~707
[75] 陈永清,夏庆霖,刘红光.2003.黑色页岩建造中的贵金属矿产评价研究.地球物理学进展,18(2):261~268
[76] 陈智梁,陈世瑜.1987.扬子地块西缘地质构造演化.重庆:重庆出版社
[77] 成杭新,谢学锦,严光生,等.1998.中国泛滥平原沉积物中铂、钯丰度值及其地球化学省的初步研究.地球化学,27(2):101~107
[78] 池顺都,赵鹏大.2000.地质建造组合熵异常与找矿有利地段圈定.现代地质,14(4):423~428
[79] 池顺都,赵鹏大,刘粤湘.2001.研究矿床时间谱系的GIS途径.地球科学,26(2):180~184
[80] 邓晋福,莫宣学,赵海玲,等.1999中国东部燕山期岩石圈-软流圈系统大灾变与成矿环境.矿床地质,18(4):309~315
[81] 杜杨松.1999.壳幔成矿学初探.矿床地质,18(4):341~346
[82] 范德江,刘仲衡.1995.滇东非海相泥盆纪地层研究——滇东曲靖晚志留世—早泥盆世早期沉积环境.青岛海洋大学学报,25(2):239~246
[83] 范德廉,叶杰,杨瑞英,等.1987.扬子地台前寒武—寒武纪界线附近的地质事件与成矿作用.沉积学报,5(3):81~95
[84] 范德廉,张涛,叶杰等.2000.与黑色岩系有关的超大型矿床.见:中国超大型矿床(Ⅰ)(涂光炽等著).北京:科学出版社,204~218
[85] 冯本智.1989.论扬子准地台西缘前震旦纪基底及其成矿作用.地质学报,(4):338~348
[86] 冯本智,卢民杰,张治中.等.1990.康滇地区前震旦纪地质与成矿.北京:地质出版社
[87] 冯增昭,金振奎,杨玉卿,等.1994.滇黔桂地区二叠纪岩相古地理.北京:地质出版社
[88] 冯增昭,彭勇民,金振奎,等.2001.中国南方寒武纪和奥陶纪岩相古地理.北京:地质出版社
[89] 高振敏,罗泰义,李胜荣.1997.黑色岩系中贵金属富集层的成因:来自固定铵的佐证.地质地球化学,No.1:18~23
[90] 龚琳,何毅特,陈天佑,等.1996.云南东川元古宙裂谷型铜矿.北京:冶金工业出版社
[91] 国务院.2006.国务院关于加强地质工作的决定.国发(2006)4号
[92] 国土资源部.2004.我国重要矿产资源保障程度与开发利用.内部资料
[93] 国土资源部信息中心.2004.世界矿产资源年评(2002~2003).北京:地质出版社
[94] 国务院新闻办公室.2003.《中国的矿产资源政策》白皮书
[95] 何起祥.1978.沉积岩和沉积矿床.北京:地质出版社
[96] 何廷贵.1989.滇东渔户村组含磷岩系的划分与对比.矿物岩石,9(2):1~12
[97] 赫尔伯特LJ等.(沈承珩,刘道荣译).1991.铂族元素的地质环境.北京:地质出版社,101~107
[98] 黄汲清.1954.中国主要地质构造单位(英文-地质专报-甲种-20号,1945),(中译本).北京:地质出版社
[99] 江能人,王尊周,陈永光.1964.滇东地区寒武纪地层的探讨.地质学报,44(2):137~156
[100] 李昌年.1986.四川攀西裂谷带峨眉玄武岩的岩石学及其成因研究.地球科学,11(6):577~584
[101] 李复汉,覃嘉铭,中玉连,等.1988.康滇地区的前震旦系.重庆:重庆出版社
[102] 李红,王东坡,高福红,等.1994.吉林省中、新生代黑色页岩(油页岩)中某些金属元素富集特征.长春地质学院学报,24(3):291~297
[103] 李胜荣,高振敏,陈南生.1994.试论铂族元素地球化学示踪体系.矿物岩石地球化学通报,No.1:36~37
[104] 李胜荣,高振敏.1994.黑色岩系中铂族元素地质地球化学研究概况及其意义.地质地球化学,No.4:45~49
[105] 李胜荣,高振敏.1995.湘黔地区牛蹄塘组黑色岩系稀土特征——兼论海相热水沉积岩稀土模式.矿物学报,15(2):225~229
[106] 李胜荣,高振敏.1996.湘黔地区下寒武统黑色岩系热演化条件.地质地球化学,4:30~34
[107] 李胜荣,高振敏.2000.湘黔寒武系底部黑色岩系贵金属元素来源示踪.中国科学(D辑),30(2):169~174
[108] 李胜荣,肖启云,申俊峰,等.2002.贵州遵义下寒武统黑色岩系中贵金属的表生活动性初探.自然科学进展,12(6):612~616
[109] 李胜荣,肖启云,申俊峰,等.2002.湘黔下寒武统铂族元素来源与矿化年龄的Re-Os同位素制约.中国科学(D辑),32(7):568~575
[110] 梁有彬,李艺.1997.中国铂族元素矿床类型和地质特征.矿产与地质,11(3):145~151
[111] 梁有彬,朱文凤.1995.湘西北天门山地区镍钼矿床铂族元素富集特征及成因探讨.地质找矿论丛,10(1):55~65
[112] 林建英.1985.中国西南三省二叠纪玄武岩系的时空分布及其地质特征.科学通报,12:929~932
[113] 刘宝珺、许效松、潘杏南,等.1993.中国南方古大陆沉积地壳演化与成矿.北京:科学出版社
[114] 刘本培,蔡运龙,等.2000.地球科学导论.北京,高等教育出版社
[115] 刘秉光.2002.中国PGE矿床类型分析.地质与勘探,38(4):1~7
[116] 刘朝基,曾绪伟,金久堂,等.1988.康滇地区基性超基性岩.重庆,重庆出版社,227~231
[117] 刘家铎,张成江,刘显凡,等.2004.扬子地台西南缘成矿规律及找矿方向.北京:地质出版社,130~185
[118] 刘玉强,龚羽飞.2004.我国主要矿产资源及矿产品供需形势分析与对策建议.地质与矿产,18(3):294-296
[119] 卢家烂,庄汉平,傅家谟.1999.湖北兴山白果园黑色页岩型银钒矿床中银钒赋存状态研究.地球化学,28(3):222~230
[120] 罗惠麟,蒋志文,何廷贵.1982.川滇地区震旦系—寒武系界线.地质科学,2:215~219
[121] 罗惠麟,蒋志文,唐良栋.1994.中国下寒武统建阶层型剖面.昆明:云南科技出版社
[122] 罗惠麟,蒋志文,武希彻,等.1982.云南东部震旦系—寒武系界线.昆明:云南人民出版社
[123] 罗惠麟,蒋志文,邢裕盛,等.1984.中国云南晋宁梅树村震旦系—寒武系界线层型剖面.昆明:云南人民出版社
[124] 罗惠麟,蒋志文,徐重九,等.1980.云南晋宁梅树村、王家湾震旦系—寒武系界线研究.地质学报,54(2):95~112
[125] 罗惠麟,武希彻,欧阳麟.1991.云南东部震旦系—寒武系界线地层的相变与横向对比.岩相古地理,(4):27~35
[126] 罗君烈.1995.云南铂、铜镍、铬矿的成矿床模式.云南地质,14(4):311~318
[127] 骆耀南.1985.中国攀枝花—西昌古裂谷带,中国攀西裂谷文集1.北京:地质出版社
[128] 钱逸,朱茂炎,何廷贵,等.1996.再论滇东前寒武系与寒武系界线剖面.微体 古生物学报,13(3):225~240
[129] 沈发奎.1989.攀西裂谷火山岩系某些成因特点的地球化学证据.地球化学,2:158~165
[130] 孙晓明,王敏,薛婷,等.2003.华南下寒武统黑色岩系铂多金属矿中黄铁矿流体包裹体的Hc-Ar同位素体系.高效地质学报,9(4):661~666
[131] 唐朝京,雷菁.2003.信息论与编码基础.长沙:国防科技大学出版社
[132] 唐良栋.1994.云南东部早寒武世沉秘相古地理.云南地质,13(3):240-252
[133] 陶奎元,毛建仁,刑光祸,等.1999.中国东部燕山期火山-岩浆大爆发.矿床地质,18(4):316~322
[134] 涂光炽.1999.贵金属找矿中若干问题的讨论.论当代矿产资源勘查评价的理论与方法,陈毓川主编.北京:地震出版社,186~191
[135] 万天丰.2004.中国大地构造学纲要.北京:地质出版社
[136] 王宝禄,李文昌.2001.西南三江(中南段)褶皱带及邻区深部地质构造一些问题探讨.见:应用物探资料研究重点成矿区带的区域构造和成矿构造文集(孙文珂,黄崇轲,丁鹏飞等著).北京:地质出版社,118~129
[137] 王敏,孙晓明,马名扬.2004.华南黑色岩系铂多金属成矿流体地球化学及其矿床成因意义.中山大学学报(自然科学版),43(5):98~102
[138] 王世称.2005.大型、超大型矿床定量预测.全国数学地质、矿产资源评价及GIS应用研讨会,湖北,武汉
[139] 王学求.1998.深穿透勘查地球化学.物探与化探,22(3):166~169
[140] 王学求.2004.新类型难识别矿地球化学勘查.物探与化探,28(3):202~205
[141] 王砚耕,王尚彦.2003.峨眉山大火成岩省与玄武岩铜矿——以贵州二叠纪玄武岩分布区为例.贵州地质,26(1):5~10
[142] 王祖英,江能人,谭雪春,袁品泉等.1995.云南岩相古地理图集.昆明:云南科技出版社
[143] 吴朝东,陈其英,杨承运.1999.湘西黑色岩系沉积演化与含矿序列.沉积学报,17(2):168~175
[144] 吴朝东,储著银.2001.黑色页岩微量元素形态分析及地质意义.矿物岩石地球化学通报,20(1):14~20
[145] 吴朝东,申延平,侯泉林.2001.湘西黑色岩系铂族元素地球化学特征及富集因素.自然科学进展,11(5):507~513
[146] 吴朝东,杨承运,陈其英.1999.湘西黑色岩系地球化学特征和成因意义.岩石矿物学杂志,18(1):26~39
[147] 吴朝东.2000.湘西震旦—寒武纪交替时期古海洋环境的恢复.地学前缘,7(增刊):45~57
[148] 吴上龙,陈元坤,李丽辉,等.1990.云南省区域物化探资料综合研究报告(内部资料).134-140
[149] 吴应林,朱忠发,王吉礼,等.1989.上扬子台地早、中三叠世岩相古地理及沉积矿产的环境控制.重庆:重庆出版社
[150] 夏庆霖,赵鹏大.2002.致矿地质异常解析.2002国际数学地质研讨会论文集, 31~32
[151] 夏庆霖,陈永清,赵鹏大.2003.滇东Pt-Pd地球化学填图及其异常评价.地质通报,22(9):704~707
[152] 夏庆霖,张寿庭,赵鹏大,等.2003.幂律度与成矿预测.成都理工大学学报(自然科学版),30(5):453~456
[153] 谢学锦.1979.区域化探.北京:地质出版社,118~124
[154] 谢学锦.1997.矿产勘查的新战略.物探与化探,21(6):402~410
[155] 谢学锦,邵跃,王学求.1999.走向211世纪矿产勘查地球化学.北京:地质出版社
[156] 谢学锦.2001.进入21世纪的勘查地球化学.中国地质,28(4):11~18
[157] 谢学锦,王学求.2003.深穿透地球化学新进展.地学前缘,10(1):225~238
[158] 邢树文,孙景贵,刘洪文.2002.高碳黑色页岩型铂族元素矿床的成矿性探讨.地质与勘探,38(6):17~21
[159] 熊兴武,侯蜀光,薛顺荣.1995.滇中昆阳群因民组地层学与岩相古地理.武汉:中国地质大学出版社
[160] 杨剑,易发成,侯兰杰.2004.黔北黑色岩系的岩石地球化学特征和成因.矿物学报,24(3):285~289
[161] 杨剑,易发成,刘涛,等.2005.黔北黑色岩系稀土地球化学特征及成因意义.地质科学,40(1):84~94
[162] 杨荆舟,罗君烈,赵准.1998.云南矿床区域成矿模式.云南地质,增刊:1~134
[163] 杨勤生.2001.云南东部及邻区黑色岩系内的矿床(化)特征与找矿设想.云南地质,20(1):59~72
[164] 杨瑞瑛,黄忠祥,李继亮.1985.攀西裂谷火成岩组合的微量元素地球化学.中国科学B,9:844~854
[165] 杨星,杨宗镜.1991.铂族元素成矿模式新发展与找矿设想.当代地质科学技术进展,7~10
[166] 叶杰,范德廉.2000.黑色岩系型矿床的形成作用及其在我国的产出特征.矿物岩石地球化学通报,19(2):95~102
[167] 叶天竺,朱裕生,夏庆霖,等.2004.固体矿产预测评价方法技术.北京:中国大地出版社
[168] 易发成,杨剑,侯兰杰,等.2004。黔北黑色岩系的铂族元素地球化学特征及成因探讨.地质科学,39(3):367~374
[169] 于炳松,H.Dong,E.Widom,等.2004.塔里木盆地北部下寒武统底部黑色页岩Os-Re和Nd同位素特征及其与样子地台的对比.中国科学(D辑),34(增刊Ⅰ):83~88
[170] 于炳松,陈建强,李兴武,等.2002.塔里木盆地下寒武统底部黑色页岩地球化学特征及其岩石圈演化意义.中国科学(D辑),32(5):374~382
[171] 於崇文.2003.地质系统的复杂性.北京:地质出版社
[172] 袁学诚.1989.论康滇地轴的深部构造.地质学报,(1):1~13
[173] 云南省地质局第二区域地质调查大队.1980.1:20万区域地质调查报告——东 川幅(矿产部分).46~50
[174] 云南省地质矿产局.1990.云南省区域地质志.北京:地质出版社
[175] 翟裕生,邓军,李晓波,等.1999.区域成矿学.北京:地质出版社
[176] 翟裕生,邓军,汤中立,等.2002.古陆边缘成矿系统.北京:地质出版社
[177] 翟裕生,彭润民,王建平,等.2003.成矿系列的结构模型研究.高校地质学报,9(4):510~519
[178] 翟裕生,王建平,邓军,等.2002.成矿系统与矿化网络研究.矿床地质,21(2):106~112
[179] 张爱云,伍大茂,郭丽娜,等.1987.海相黑色页岩建造地球化学与成矿意义.北京:科学出版社
[180] 张春晖译.1997.黑色板岩金矿中铂族元素的存在形式.贵金属地质,6(1):77~80
[181] 张光弟,李九玲,熊群尧,等.2002.贵州遵义黑色页岩铂族金属富集特点及富集模式.矿床地质,21(4):377~386
[182] 张光弟,毛景文,熊群尧.2001.中国铂族金属资源现状与前景.地球学报,22(2):107~110
[183] 张光前,李继英.1991.定量岩石地层学.武汉:中国地质大学出版社
[184] 张洪,陈方伦.1996.铂组元素分析方法、矿床地球化学及地球化学勘查.北京:地质出版社
[185] 张俊明,李国祥,周传明.1997.滇东下寒武统含磷岩系底部火山喷发事件沉积及其意义.地层学杂志,21(2):91~155
[186] 张乾,董振生,战新志.1995.鄂西白果园黑色页岩型银钒矿床地球化学特征.矿物学报,15(2):185~191
[187] 张翼飞.1993.云南省区域矿产总结.5~20
[188] 张振飞,夏庆霖.2005.成矿环境空间结构的模糊建模.地球科学,30(1):109~113
[189] 赵鹏大.1982.试论地质体的数学特征.地球科学,7(1):145~155
[190] 赵鹏大,孟宪国.1993.地质异常与矿产预测.地球科学,18(1):39~47
[191] 赵鹏大,陈建平,张寿庭.2003.“三联式”成矿预测新进展.地学前缘,10(2):455~463
[192] 赵鹏大.2001.地球科学的新使命——认知和发现非传统矿产资源.地球物理学进展,16(4):127~132
[193] 赵鹏大,陈建平,陈建国.2001.成矿多样性与矿床谱系.地球科学,26(2):111~117
[194] 赵鹏大,陈建甲.2000.非传统矿产资源体系及其关键科学问题.地球科学进展,15(3):251~255
[195] 赵鹏大,陈永清,刘吉平,等.1999.地质异常成矿预测理论与实践.武汉:中国地质大学出版社
[196] 赵鹏大,池顺都,陈永清.1996.查明地质异常:成矿预测的基础.高校地质学报,2(4):361~373
[197] 赵鹏大,池顺都.1991.初论地质异常.地球科学——中国地质大学学报,16(3):241~248
[198] 赵鹏大,王京贵,饶明辉等.1995.中国地质异常.地球科学——中国地质大学 学报,20(2):117~127
[199] 赵鹏大等.2003.非传统矿产资源概论.北京:地质出版社
[200] 郑大中.1997.铂族元素迁移富集机理的新探.四川地质学报,17(2):148-156
[201] 郑玉清.2001.云南省东川—曲靖地区地质异常与铂钯成矿预测.中国地质大学:工程硕士学位论文
[202] 中国科学院地质研究所.1959.中国大地构造纲要.北京:科学出版社
[203] 朱炳泉,常向阳,邱华宁,等.2000.扬子地台西南缘滇中元古宇特征及赋存超大型矿床的可能性.见:中国超大型矿床(Ⅰ)(涂光炽等著).北京:科学出版社,95~116
[204] 朱笑青,王中刚,陈南生.1996.镍钼在黑色岩系中富集成因的实验研究.大地构造与成矿学,20(4):368~374
[205] 庄汉平,卢家烂,傅家谟,等.1998.湖北兴山白果园黑色页岩型银钒矿床改造成矿作用的证据.科学通报,1328~1332