Leech M L. Arrested orogenic development: Eclogitization, delamination and tectonic collapse[J]. Earth and Planetary Science Letters, 2001, 185: 149-159.
[2]
Turner G, Burnard P, Ford J L, et al. Tracing fluid sources and interactions[J]. Philosophical Transactions of the Royal Society of London,1993, 344: 127-140.
Qu Xiaoming, Hou Zengqian, Guo Lianjie, et al. Compositions and crustal contaminations of adakitic ore-bearing porphyries in the Gangdise Copper Belt:Nd, Sr, Pb and O isotope constraints[J]. Acta Geologica Sinica, 2004, 78(6): 813-821.[曲晓明, 侯增谦, 国连杰, 等. 冈底斯铜矿带埃达克质含矿斑岩的源区组成与地壳混染: Nd、Sr、Pb、O 同位素约束[J]. 地质学报, 2004, 78(6): 813-821.]
[5]
Li Wuping, Li Xianhua, Lu Fengxiang, et al. Geolocail characteristics and its setting for volcanic rocks of early Cretaceous Yixian Formation in western Liaoning Province, eastern China[J]. Acta Petrologica Sinica, 2002, 18(2): 193-204.[李伍平, 李献华, 路凤香, 等. 辽西早白垩世义县组火山岩的地质特征及其构造背景[J]. 岩石学报, 2002, 18(2): 193-204.]
[6]
Wang Qiang, Zhao Zhenhua, Xu Jifeng, et al. Adakite-like rocks and mineralization in Yanshan period from eastern Yangtze Block[J]. Science in China(Series D), 2002, 32(Suppl.):127-136.[王强,赵振华,许继峰,等.扬子地块东部燕山期埃达克质(adakite-like)岩与成矿[J].中国科学:D辑,2002,32(增刊) :127-136.]
[7]
Wang Qiang, Zhao Zhenhua, Xiong Xiaolin, et al. Melting of the underplated basaltic lower crust: Evicence from the Shaxi adakitic sodic quartz diorite-pophyrites, Anhui Province, China[J]. Geochimica, 2001, 30(4) : 353-362.[王强, 赵振华, 熊小林, 等. 底侵玄武下地壳的熔融:来自安徽沙溪adakite质富钠石英闪长玢岩的证据[J]. 地球化学, 2001, 30(4) : 353-362.]
[8]
Hou Z Q , Gao Y F , Qu X M , et al. Origin of adakitic intrusives generated during mid-Miocene east-west extension in sout hern Tibet[J]. Earth and Planetary Science Letters, 2004,220:139-155.
[9]
Hou Zengqian. Porphyry Cu-Mo-Au Deposits: Some new insights and advances[J]. Earth Science Froniters, 2004, 11(1): 132-139.[侯增谦.斑岩Cu- Mo-Au矿床:新认识与新进展[J]. 地学前缘, 2004, 11(1): 132-139.]
[10]
Marending M, Luder H U, Brunner T J, et al. Effect of sodium hypochlorite on human root dentine-mechanical, chemical and structural evaluation[J]. International Endodontic Journal, 2007, 40(10): 786-793.
[11]
Gao Heming. A summary of researches on porphyry copper deposits[J]. Advances in Earth Science, 1995, 10(1): 40-46.[高合明.斑岩铜矿床研究综述[J]. 地球科学进展, 1995, 10(1): 40-46.]
[12]
Ma Ying. Development of porphyry copper deposit research and expectation[J]. Werstern Exploration Engineering, 2007,(9):89-92.[马瑛.斑岩铜矿的研究现状与展望[J]. 西部探矿工程, 2007, (9):89-92.]
[13]
Li Xiaofeng, Liang Jincheng, Feng Zuohai, et al. Development of porphyry copper deposit research[J]. Journal of Guilin University of Technology, 2009,29(2):216-222.[李晓峰,梁金城,冯佐海,等.斑岩铜矿研究最新进展[J].桂林工学院学报,2009,29(2):216-222.]
[14]
Hou Zengqian, Lü Qingtian, Wang Anjian, et al. Continental collision and related metallogeny:A case study of mineralization in Tibetan Orogen[J]. Mineral Deposits, 2003, 22(4): 319-333.[侯增谦,吕庆田,王安建,等.初论陆—陆碰撞与成矿作用——以青藏高原造山带为例[J].矿床地质, 2003, 22(4): 319-333.]
[15]
Hou Zengqian, Mo Xuanxue, Gao Yongfeng, et al. Adakite, a possible host rock for porphyry copper deposits: Case studies of porphyry copper belts in Tibetan Plateau and in Northern Chile[J]. Mineral Deposits, 2003,22(1):1-12.[侯增谦,莫宣学,高永丰,等.埃达克岩:斑岩铜矿的一种可能的重要含矿母岩——以西藏和智利斑岩铜矿为例[J].矿床地质, 2003, 22(1):1-12.]
[16]
Hou Zengqian, Qu Xiaoming, Wang Shuxian, et al. Molybdenite Re-Os age in Tibetan Plateau porphyry copper ore belt: Mineralization time and dynamic background applications[J]. Science in China(Series D), 2003, 33(7): 609-618.[侯增谦,曲晓明,王淑贤,等.西藏高原冈底斯斑岩铜矿带辉钼矿Re-Os 年龄: 成矿作用时限与动力学背景应用[J].中国科学:D辑, 2003, 33(7) : 609-618.]
[17]
Hou Zengqian, Gao Yongfeng, Meng Xiangjin, et al. Genesis of adakitic porphyry and tectonic controls on the Gangdes Miocene porphyry copper belt in the Tibetan orogen[J]. Acta Petrologica Sinica, 2004, 20(2):239-248.[侯增谦,高永丰,孟祥金,等.西藏冈底斯中新世斑岩铜矿带:埃达克质斑岩成因与构造控制[J].岩石学报,2004,20(2):239-248.]
[18]
Hou Zengqian, Mo Xuanxue, Yang Zhiming, et al. Metallogeneses in the collisional orogen of the Qinghai-Tibet Plateau: Tectonic setting, tempo-spatial distribution and ore deposit types[J].Geology in China, 2006, 33(2): 340-351.[侯增谦,莫宣学,杨志明,等.青藏高原碰撞造山带成矿作用:构造背景,时空分布和主要类型[J].中国地质, 2006, 33(2): 340-351.]
[19]
Hou Zengqian, Qu Xiaoming, Yang Zhusen, et al. Metallogenesis in Tibetan collisional orogenic belt: Ⅲ Mineralization in post-collisional extension setting[J]. Mineral Deposits, 2006, 25(6):629-651.[侯增谦,曲晓明,杨竹森,等.青藏高原碰撞造山带:Ⅲ.后碰撞伸展成矿作用[J].矿床地质, 2006, 25(6):629-651.]
[20]
Hou Zengqian, Pan Xiaofei, Yang Zhiming, et al. Porphyry Cu-(Mo-Au) deposits no related to oceanic-slab subduction examples from Chinese porphyry deposits in continental settings[J]. Geoscience, 2007, 21(2): 332-351.[侯增谦,潘小菲,杨志明,等.初论大陆环境斑岩铜矿[J].现代地质, 2007, 21(2): 332-351.]
[21]
Yang Zhiming, Hou Zengqian. Porphyry Cu deposits in collisional orogen setting: A preliminary genetic model[J]. Geoscience, 2009, 28(5): 515-538.[杨志明,侯增谦.初论碰撞造山环境斑岩铜矿成矿模型[J].矿床地质, 2009, 28(5): 515-538.]
[22]
Sillitoe R H. A plate tectonic model for the origin of porphyry copper deposits[J]. Economic Geology,1972, 67(2): 184-197.
[23]
Titley S R, Beane R E. Porphyry copper deposits: Part I. Geology settings, petrology, and tectogenesis[J]. Economic Geology, 1981, 75: 214-269.
[24]
Zhang Hongtao, Chen Renyi, Han Fanglin. Reunderstanding of metallogenic geological conditions of porphyry copper deposits in China[J]. Mineral Deposits,2004, 23(2): 150-163.[张洪涛,陈仁义,韩芳林.重新认识中国斑岩铜矿的成矿地质条件[J].矿床地质, 2004, 23(2): 150-163.]
[25]
Zhang Hongtao, Rui Zongyao. Geological setting of the porphyry copper deposit series of China[J]. Acta Geologica Sinica,1991,(3):250-262.[张洪涛, 芮宗瑶.论中国斑岩铜矿系列的地质背景[J].地质学报,1991,(3):250-262.]
[26]
Rui Zongyao, Hou Zengqian, Qu Xiaoming, et al. Metallogenetic epoch of Gangdese porphyry copper belt and uplift of Qinghai Tibet Plateau[J]. Mineral Deposits, 2003,22(3):217-225.[芮宗瑶,侯增谦,曲晓明,等.冈底斯斑岩铜矿成矿时代及青藏高原隆升[J].矿床地质,2003,22(3):217-225.]
[27]
Rui Zongyao, Zhang Lisheng, Chen Zhenyu, et al. Approach on source rock or source region of porphyry copper deposits[J]. Acta Petrologica Sinica, 2004, 20(2): 229-238.[芮宗瑶,张立生,陈振宇,等. 斑岩铜矿的源岩或源区探讨[J].岩石学报,2004,20(2):229-238.]
[28]
Rui Zongyao, Zhang Hongtao, Chen Renyi, et al. An approach to some problems of porphyry copper deposits[J]. Mineral Deposits, 2006, 25(4):491-499.[芮宗瑶,张洪涛,陈仁义,等. 斑岩铜矿研究中若干问题探讨[J].矿床地质,2006,25(4):491-499.]
[29]
Yao Chunliang, Lu Jianjun, Guo Weimin, et al. The latest advances in researches on porphyry copper deposits[J]. Mineral Deposits,2007, 26(2): 221-229.[姚春亮,陆建军,郭维民,等.斑岩铜矿若干问题的最新研究进展[J].矿床地质,2007,26(2): 221-229.]
[30]
Zeng Pusheng, Hou Zengqian, Gao Yongfeng, et al.The himalayan Cu-Mo-Au mineralization in the Eastern Indo-Asian collision zone: Constraints from Re-Os dating of Molybdenite[J].Geological Review, 2006, 52(1):72-84.[曾普胜,侯增谦,高永峰,等.印度—亚洲碰撞带东段喜马拉雅期铜—钼金矿床Re-Os 年龄及成矿作用[J].地质论评,2006,52(1):72-84.]
[31]
Gustafson L B. Some major fact ors of porphyry copper genesis[J]. Economic Geology, 1978, 73(5): 600- 607.
[32]
Pirajno F. Hydrothermal Mineral Deposits: Principles and Fundamental Concepts for the Exploration Geologist[M]. Verlag: Springer, 1992: 325-374.
[33]
Mitchell A H G. Metallogenic belts and angle of dip of Benioff zones[J]. Nature, 1973, 245 (143): 49-52.
[34]
James D, Sacks I S. Cenozoic formation of the central Andes: A geophysical perspective[C]∥Skinner B F, ed. Society of Economic Geologists Special Publication, 1999:1-25.
[35]
Rosenbaum G, Giles D, Saxon M, et al. Subduction of the Nazca Ridge and the Inca Plateau: Insights into the formation of ore deposits in Peru[J]. Earth and Planetary Science Letters, 2005, 239(1/2):18-32.
[36]
Cooke D R, Hollings P, Walsh J L. Giant porphyry deposits: Characteristics, distribution, and tectonic controls[J]. Economic Geology, 2005, 100(5):801-818.
[37]
Sillitoe R H. Characteristics and controls of the largest porphyry copper-gold and epithermal gold deposits in the circum-Pacif ic region[J]. Australian Journal of Earth Sciences, 1997, 44(3): 373-388.
[38]
Uyeda S, Nishiwaki C. Stress field, metallogenesis and mode of subduction: The continental crust and its mineral resources[J]. Geological Association of Canada, 1980, 20: 323-339.
[39]
Richards J P. Tectono-magmatic precursors for porphyry Cu-(Mo-Au) deposit formation[J]. Economic Geology, 2003, 98 (8):1 515-1 533.
[40]
Masterman G J, Cooke D R, Berry R F, et al. Fluid chemistry, structural setting, and emplacement history of the Rosario Cu-Mo porphyry and Cu-Ag-Au epithermal veins, Collahuasi district, northern Chile[J]. Economic Geology, 2005, 100: 835-862.
[41]
Takada A. The influence of regional stress and magmatic input on styles of monogenetic and polygenetic volcanism[J]. Journal of Geophysical Research, 1994, 99: 13 563-13 573.
[42]
Sillitoe R H. Porphyry copper systems[J]. Economic Geology, 2010, 105(1): 3-41.
[43]
Tosdal R M, Richards J P. Magmatic and structural controls on the development of porphyry Cu±Mo±Au deposits[J]. Reviews in Economic Geology, 2001,14: 157-181.
[44]
Presnell R D. Structural controls on the plutonism and metallogeny in the Wasatch and Oquirrh Mountains, Utah[J]. Society of Economic Geologists Guidebook Series, 1997, 29: 1-9.
[45]
Sasso A M, Clark A H. The farallón negro group, northwest Argentina: Magmatic, hydrothermal and tectonic evolution and implication for Cu-Au metallogeny in the Andean back-arc[J]. Society of Economic Geologists Newsletter, 1998, 34 (1): 8-18.
[46]
Halter W E, Bain N, Becker K, et al. From andesitic volcanism to the formation of a porphyry Cu-Au mineralizing magma chamber: The farallón negro volcanic complex, northwestern Argentina[J]. Journal of Volcanology and Geothermal Research, 2004, 136:1-30.
[47]
Richards J P, Boyce A J, Pringle M S. Geologic evolution of the Escondida area, northern Chile: A model for spatial and temporal localization of porphyry Cu mineralization[J]. Economic Geology, 2001, 96 (2): 271-305.
[48]
Lowell J D, Guilbert J M. Lateral and vertical alteration-mineralization zoning in porphyry ore deposits[J]. Economic Geology, 1970, 65:373-408.
[49]
Hollister V F. Geology of the Porphyry Copper Deposits of the Western Hemisphere[M]. Minneapolis: Society of Mining Engineers of the American Institute of Mining, Metallurgical, and Petroleum Engineers, 1978.
[50]
Dewey J F. Episodicity, sequence and style at convergent plate boundaries[J]. Geological Association of Canada Special Paper, 1980, 20: 553-573.
[51]
Hedenquist J W, Richards J P. The influence of geochemical techniques on the development of genetic models for porphyry copper deposits[J]. Reviews in Economic Geology, 1998, 10: 235-256.
[52]
Singer D A, Menzie W D, Berger B R. Porphyry copper deposit density[J]. Economic Geology, 2005,100: 491-514.
[53]
Ulrich T, Heinrich C A. Geology and alteration geochemistry of the porphyry Cu-Au deposit at Bajo de la Alumbrera, Argentina[J]. Economic Geology, 2001, 96: 1 719-1 742.
[54]
Mueller D, Groves D I. Potassic Igneous Rocks and Associated Gold-Copper Mineralization(3rd)[M]. Berlin: Springer, 2000: 252.
[55]
Thieblemont D, Stein G, Lescuyer J L. Epithermal and porphyry deposits: The adakitic connection[J]. Earth and Planetary Sciences, 1997, 329:243-250.
[56]
McInnes B I A, Cameron E M. Carbonated, alkaline hybridizing melts from a sub-arc environment: Mantle wedge samples from the Tabar-Lihir-Tanga-Feni arc, Papua New Guinea[J]. Earth and Planetary Science Letters, 1994, 122 (1): 125-141.
[57]
Rush P M, Seegers H J. Ok Tedi copper-gold deposits[J]. Australasian Institute of Mining and Metallurgy Monograph,1990, 14(2): 1 747-1 754.
[58]
Ishihara S. The granitoid series and mineralization[J].Economic Geology, 1981,75: 458-484.
[59]
Seedorff E, Dilles J H, Proffett J M, et al. Porphyry deposits: Characteristics and origin of hypogene features[J]. Economic Geology, 2005,100: 251-298.
[60]
Enns S G, Thompson J F H, Stanley C R, et al. The Galore Creek porphyry copper-gold deposits, northwestern British columbia[J]. Canadian Institute of Mining, Metallurgy and Petroleum, 1995,46: 630-644.
[61]
Kósaka K, Wakita K. Some geological features of the Mamut porphyry copper deposit, Sabah, Malaysia[J]. Economic Geology, 1978, 73: 618-627.
[62]
Meyer C, Hemley J J. Wall rock alteration[M]∥Barnes H L, ed. Geochemistry of Hydrothermal Ore Deposits. New York: Holt, Rinehart and Winston, 1967: 166-235.
[63]
Ford J H. A chemical study of alteration at the Panguna porphyry copper deposit, Bougainville, Papua New Guinea[J]. Economic Geology, 1978, 73: 703-720.
[64]
Cannell J, Cooke D R, Walshe J L, et al. Geology, mineralization, alteration, and structural evolution of the El Teniente porphyry Cu-Mo deposit[J]. Economic Geology, 2005,100: 979-1 003.
[65]
Perelló J A, Fleming J A, O’Kane K P, et al. Porphyry copper-gold-molybdenum deposits in the Island copper cluster, northern Vancouver Island, British Columbia[J]. Canadian Institute of Mining, Metallurgy and Petroleum, 1995, 46: 214-238.
[66]
Arancibia O N, Clark A H. Early magnetite-amphibole-plagioclase alteration-mineralization in the Island copper porphyry copper-goldmolybdenum deposit, British Columbia[J]. Economic Geology, 1996, 91: 402-438.
[67]
Sillitoe R H, Gappe I M. Philippine Porphyry Copper Deposits: Geologic Setting and Characteristics[M]. Bangkok, Thailand: United Nations ESCAP, CCOP Technical Publication, 1984, 14: 89.
[68]
Wilson A J, Cooke D R, Harper B R. The ridgeway gold-copper deposit: A high-grade alkalic porphyry deposit in the Lachlan fold belt, New South Wales, Australia[J]. Economic Geology, 2003, 98: 1 637-1 666.
[69]
Perelló J, Neyra C, Posso H, et al. Cotabambas: Late Eocene Porphyry Copper-Gold Mineralization Southwest of Cuzco[M]. Peru: Society of Economic Geologists Special Publication, 2004: 213-230.
[70]
Titley S R. The style and progress of mineralization and alteration in porphyry copper systems: American Southwest[M]∥Titley S R, ed. Advances in Geology of the Porphyry Copper Deposits, Southwestern North America. Tucson: University of Arizona Press, 1982: 93-116.
[71]
Rusk B G, Reed M H, Dilles J H, et al. Compositions of magmatic hydrothermal fluids determined by LAICP-MS of fluid inclusions from the porphyry copper-molybdenum deposit at Butte, MT[J]. Chemical Geology, 2004, 210: 173-199.
[72]
Rusk B G, Reed M H, Dilles J H. Fluid inclusion evidence for magmatic-hydrothermal fluid evolution in the porphyry copper-molybdenum deposit at Butte, Montana[J]. Economic Geology,2008, 103: 307-334.
[73]
Ambrus J. Geology of the El Abra porphyry copper deposit, Chile[J]. Economic Geology, 1977, 72: 1 062-1 085.
[74]
Dean D A, Graichen R E, Barrett L F, et al. Geologic overview of the El Abra porphyry copper deposit, Chile[M]∥Green S M, Struhsacker E, eds. Geology and Ore Deposits of the American Cordillera. Field Trip Guidebook Compendium: Reno, Geological Society of Nevada, 1996: 457-464.
[75]
Proffett J M. Geology of the Bajo de la Alumbrera porphyry copper-gold deposit, Argentina[J]. Economic Geology, 2003, 98: 1 535-1 574.
[76]
Perelló J, Brockway H, Martini R. Discovery and geology of the esperanza porphyry copper-gold deposit, Antofagasta region, Northern Chile[J]. Society of Economic Geologists,2004,11: 167-186.
[77]
Harris A C, Golding S D, White N C. Bajo de la Alumbrera copper-gold deposit: Stable isotope evidence for a porphyry-related hydrothermal system dominated by magmatic aqueous fluids[J]. Economic Geology, 2005, 100: 863-886.
[78]
Bouzari F, Clark A H. Prograde evolution and geothermal affinities of a major porphyry copper deposit: The Cerro Colorado hypogene protore, I Región, northern Chile[J]. Economic Geology, 2006, 101: 95-134.
[79]
Gustafson L B, Hunt J P. The porphyry copper deposit at El Salvador, Chile[J]. Economic Geology, 1975, 70: 857-912.
[80]
Burnham C W. Hydrothermal fluids at the magmatic stage[M]∥Barnes H L, ed. Geochemistry of Hydrothermal Ore Deposits.New York: Holt, Rinehart and Winston, 1967: 34-76.
[81]
Hedenquist J W, Lowenstern J B. The role of magmas in the formation of hydrothermal ore deposits[J]. Nature, 1994, 370(18): 519-527.
[82]
Harris A C, Kamenetsky V S, White N C, et al. Melt inclusions in veins: Linking magmas and porphyry Cu deposits[J]. Science, 2003, 302: 2 109-2 111.
[83]
Burnham C W, Ohmoto H. Late-stage processes of felsic magmatism[J]. Mining Geology, 1980, 8: 1-11.
[84]
Candela P A, Holland H D. A mass transfer model for copper and molybdenum in magmatic hydrotheral systems: The origin of porphyry-type ore deposits[J]. Economic Geology,1986, 81: 1-19.
[85]
Nagaseki H, Hayashi K. Experimental study of the behavior of copper and zinc in a boiling hydrothermal system[J]. Geology, 2008, 36: 27-30.
[86]
Pokrovski G S, Borisova A Y, Harrichoury J C. The effect of sulfur on vapour-liquid fractionation of metals in hydrothermal systems[J]. Earth and Planetary Science Letters, 2008, 266: 345-362.
[87]
Pokrovski G S, Tagirov B R, Schott J, et al. A new view on gold speciation in sulfur-bearing hydrothermal fluids from in situ X-ray absorption spectroscopy and quantum-chemical modeling[J]. Geochimica et Cosmochimica Acta, 2009, 73: 5 406-5 427.
[88]
Ulrich T, Mavrogenes J. An experimental study of the solubility of molybdenum in H2O and KCl-H2O solutions from 500 ℃ to 800 ℃, and 150 to 300 MPa[J]. Geochimica et Cosmochimica Acta,2008, 72: 2 316-2 330.
[89]
Carten R B. Sodium-calcium metasomatism: Chemical, temporal, and spatial relationships at the Yerington, Nevada, porphyry copper deposit[J]. Economic Geology, 1986, 81: 1 495-1 519.
[90]
Seedorff E, Barton M D, Stavast W J A, et al. Root zones of porphyry systems: Extending the porphyry model to depth[J]. Economic Geology, 2008, 103: 939-956.
[91]
Bodnar R J. Fluid-inclusion evidence for a magmatic source for metals in porphyry copper deposits[J]. Mineralogical Association of Canada Short Course Series, 1995, 23: 139-152.
[92]
Williams-Jones A E, Heinrich C A. Vapor transport of metals and the formation of magmatic-hydrothermal ore deposits[J]. Economic Geology, 2005, 100: 1 287-1 312.
[93]
Hedenquist J W, Arribas A J, Reynolds T J. Evolution of an intrusion-centered hydrothermal system: Far Southeast-Lepanto porphyry and epithermal Cu-Au deposits, Philippines[J]. Economic Geology, 1998, 93: 373-404.
[94]
Heinrich C A, Driesner T, Stefánsson A,et al. Magmatic vapor contraction and the transport of gold from the porphyry environment to epithermal ore deposits[J].Geology, 2004, 32: 761-764.
[95]
Heinrich C A. The physical and chemical evolution of low-salinity magmatic fluids at the porphyry to epithermal transition: A thermodynamic study[J]. Mineralium Deposita, 2005, 39: 864-889.
[96]
Sheppard S M F, Nielsen R L, Taylor H J. Hydrogen and oxygen isotope ratios in minerals from porphyry copper deposits[J]. Economic Geology, 1971, 66: 515-542.
[97]
Taylor H J. The application of oxygen and hydrogen isotope studies to problems of hydrothermal alteration and ore deposition[J]. Economic Geology, 1974, 69: 843-883.
[98]
Bouse R M, Ruiz J, Titley S R, et al. Lead isotope compositions of Late Cretaceous and early Tertiary igneous rocks and sulfide minerals in Arizona; implications for the sources of plutons and metals in porphyry copper deposits[J]. Economic Geology, 1999, 94(2): 211-244.
Leng Chengbiao, Zhang Xingchun, Chen Yanjing, et al. Discussion on the relationship between Chinese porphyry copper deposits and adakitic rocks[J]. Earth Science Froniters, 2007, 14(5): 199-210.[冷成彪, 张兴春, 陈衍景, 等. 中国斑岩铜矿与埃达克(质)岩关系探讨[J]. 地学前缘, 2007, 14(5): 199-210.]
[101]
Hou Zengqian, Mo Xuanxue, Gao Yongfeng, et al. Adakite, a possible host rock for Porphyry copper deposits: Case studies of porphyry copper belts in Tibetan Plateau and in northern Chile[J]. Mineral Deposits, 2003, 22(1): 1-12.[侯增谦,莫宣学,高永丰,等.埃达克岩:斑岩铜矿的一种可能的含矿母岩——以西藏和智利斑岩铜为例[J]. 矿床地质, 2003, 22(1): 1-12.]
[102]
Zhang Qi, Wang Yan, Qian Qing, et al. The characteristics and tectonic-metallogenic significances of the adakites in Yanshan period from eastern China[J]. Acta Geologica Sinica, 2001, 17(2): 236-244.[张旗, 王焰, 钱青, 等. 中国东部燕山期埃达克岩的特征及其构造—成矿意义[J]. 岩石学报, 2001, 17(2): 236-244.]
[103]
Zhao Wenjin. Deep tectono-magmatic setting for metallogenesis of large porphyry copper deposits[J]. Geology in China, 2007, 34(2): 179-205.[赵文津. 大型斑岩铜矿成矿的深部构造岩浆活动背景[J]. 中国地质, 2007, 34(2): 179-205.]
[104]
Defant M J, Drummond M S. Derivation of some modern arc magmas by melting of young subducted lit hosphere[J]. Nature, 1990, 34 : 662-665.
[105]
[JP2]Zhang Qi,Wang Yan,Wang Yuanlong.On the relationship between Adakite and its tectonic setting[J].Geotectonica et Metallogenia,2003,27(2):101-108.[张旗, 王焰,王元龙.埃达克岩与构造环境[J].大地构造与成矿学,2003, 27(2):101-108.][JP]
