内蒙古毕力赫大型斑岩型金矿床:地质特征、发现过程与启示意义
|
摘要
华北板块北缘我国重要的金-多金属成矿带之一,该区经历了古生代多期板块俯冲和陆缘增生过程,构造-岩浆活动强烈,成矿地质条件优越。内蒙古毕力赫金矿床位于华北板块北缘古生代增生带内,是一个资源严重危机、濒临倒闭的国营矿山。通过对区域成矿地质条件综合分析,在矿山资源潜力评价和矿床地质特征详细研究基础上,认为矿床是形成于早古生代古亚洲洋俯冲碰撞,华北陆块北缘增生带之后,叠加晚古生代(二叠纪)陆缘火山-岩浆带背景的浅成低温-斑岩型金矿床。提出以针对性的地质科研引路,以斑岩型矿床成矿模型为指导,以有效的勘查方法技术组合配套使用为手段,适时并大胆设计验证工程,分期、分阶段有重点地加以实施的危机矿山找矿勘查增储的基本思路。通过工作,首次在毕力赫矿区外围新发现大型隐伏的独立斑岩型金矿床。矿床具有矿体规模大(单个矿体资源量超过20 t)、品位高(最高52.75×10-6)、变化小、埋深浅、金属矿物含量低(小于3%)、矿石简单、易采、易选等特点。研究表明,矿床形成于(271.3±1.7)Ma(MSWD=1.06),受NE和NW 2组构造交会部位及花岗闪长斑岩体控制,具有以斑岩体为中心,从深部到浅部、从中心到边部,由钾硅酸盐蚀变带→钾硅酸盐蚀变带+石英-绢云母化叠合带→石英-绢云母化带+中级泥化带→高岭土化带、蛋白石化带的环带特征。石英包裹体均一温度包括550℃和小于380℃的2个区间,盐度变化在0.88%~8.68%之间,H、O同位素组成指示主成矿期成矿热液为岩浆水与大气降水混合物。建立了矿床形成的描述型模型。该矿床的发现具有如下重意义:一是全国危机矿山接替资源勘查项目成功实施提供了典型示范;二是破解了本区作为典型的弧构造-岩浆环境却没有典型的大型斑岩型矿床发现这一长期困扰人们的科学谜题;三是对区域基础地质问题的重新认识提供了新线索;四是根据斑岩型矿床成群成带分布特点,为在本区及相似的环境内斑岩型矿床勘查提供了科学导向;五是基于本矿床发现的科学过程所总结出的找矿勘查思路和模型将对本区下一步找矿具有推广意义。
The north edge of North-China Plate is one of important gold-polymetal metallogenic belts. It undergone poly-periods plate subduction and continental-margin accretion of Paleozoic era, had strong structure-magmatic activity and ascendant metallogenic geological condition. The Bilihe gold deposit locates in the Paleozoic accretion zones of north edge of North-China Plate, is a state-operated mine at resource conjuncture and close to bankrupt. Based on analysis of regional metallogenic geological condition, evaluation of mine resource potential and research of field geological character, the deposit was a epithermal-porphyry type gold deposit that formed after paleo-Asia ocean subducting collision and accretion of north-margin of North-China in Early Paleozoic, superimposed continental-margin volcanic-magmatic setting of Later Paleozoic (Permian Period). This paper took pertinency geological research as guidance, porphyry type model as direction, general technique methods as means, and prospecting exploration as basic way, discovered a large concealed porphyry type gold deposit around Bilihe mine firstly. The Bilihe gold deposit had character of large scale(more than 20 t per orebody), high grade(top to 52.75×10-6), small change, shallow embedding, low content of metallic mineral(less than 3%), simple ore, and easy mine and dressing. The mineralization age of the Bilihe deposit was (271.3±1.7)Ma(MSWD=1.06). The deposit was controlled by combined part of NE and NW strike structure and granodioritic porphyry units. The zoning character of the deposit from depth to shallow, from center to border was kali-silicate alteralization zone→kali-silicate alteralization zone+quartz-sericitization congruence zone→quartz-sericitization + intermediate argilization→kaolinization and opalizztion. The homogenization temperatures of quartz had two zones of 550℃and 380℃. The salinity was 0.88%~8.68%. The character of H, O isotope indicated that the mineralizing fluid was the mixture of magmatic water and meteroric water. The describing model was established in this paper. The discovery of the Bilihe deposit had important significances as follows: 1)provided a typical example for triumphant actualizing conjuncture mine succeed resources item; 2) explained a science topic that this area as a typical arc-structure-magma setting but no typical porphyry deposit; 3)provided new clew for regional fundamental geological study; 4)offered scientific lead for porphyry deposit founding in similar setting; 5)supplied new model for forecasting prospect in this area.
The north edge of North-China Plate is one of important gold-polymetal metallogenic belts. It undergone poly-periods plate subduction and continental-margin accretion of Paleozoic era, had strong structure-magmatic activity and ascendant metallogenic geological condition. The Bilihe gold deposit locates in the Paleozoic accretion zones of north edge of North-China Plate, is a state-operated mine at resource conjuncture and close to bankrupt. Based on analysis of regional metallogenic geological condition, evaluation of mine resource potential and research of field geological character, the deposit was a epithermal-porphyry type gold deposit that formed after paleo-Asia ocean subducting collision and accretion of north-margin of North-China in Early Paleozoic, superimposed continental-margin volcanic-magmatic setting of Later Paleozoic (Permian Period). This paper took pertinency geological research as guidance, porphyry type model as direction, general technique methods as means, and prospecting exploration as basic way, discovered a large concealed porphyry type gold deposit around Bilihe mine firstly. The Bilihe gold deposit had character of large scale(more than 20 t per orebody), high grade(top to 52.75×10-6), small change, shallow embedding, low content of metallic mineral(less than 3%), simple ore, and easy mine and dressing. The mineralization age of the Bilihe deposit was (271.3±1.7)Ma(MSWD=1.06). The deposit was controlled by combined part of NE and NW strike structure and granodioritic porphyry units. The zoning character of the deposit from depth to shallow, from center to border was kali-silicate alteralization zone→kali-silicate alteralization zone+quartz-sericitization congruence zone→quartz-sericitization + intermediate argilization→kaolinization and opalizztion. The homogenization temperatures of quartz had two zones of 550℃and 380℃. The salinity was 0.88%~8.68%. The character of H, O isotope indicated that the mineralizing fluid was the mixture of magmatic water and meteroric water. The describing model was established in this paper. The discovery of the Bilihe deposit had important significances as follows: 1)provided a typical example for triumphant actualizing conjuncture mine succeed resources item; 2) explained a science topic that this area as a typical arc-structure-magma setting but no typical porphyry deposit; 3)provided new clew for regional fundamental geological study; 4)offered scientific lead for porphyry deposit founding in similar setting; 5)supplied new model for forecasting prospect in this area.
引文
Bailey J C, Geochemical criteria for a refined tectonic discrimination of orogenic andesites. Chem.Geol., 1981,32,139~159.
Ballard J R..Two age of porphyry intrusion resolved for the super-giant Chuquieamata copper deposit of northern Chile by ELA-ICP-MS and SHRIMP. Geology,2001,29(5):383.
Baptiste P J,Fouquet Y. Abundance and isotopic composition of helium in hydrothermal sulfides from the East Pacific Rise at 13N. Geochim Acta,1996,60:87~93.
Barra F,Ruiz J,Mathur R,Titley S. A Re-Os study of sulfide and minerals from the Bagdad porphyry Cu-Mo deposit,northern Arizona,USA. Mineralium Deposita,2003,38:585~596.
Beane R E and Titley S R. Porphyry copper deposits:PartⅡ.Hydrothermal alteration and mineralization.Econmic Geology 75th Anniversary Volume,1981,235~263.
Bellon H,Yumul Jr G P. Miocene to Quaternary adakites and related rocks in western Philippine arc sequences. Earth and Planetary Sciences. 2001,333: 343~350.
Blevln P L..The role of magma sourees,oxldation states and fraetzonation in determining the granlte metallogeny of eastern Australla.Transaetions of the Royal Soeiety of Edinburgh,Earth scicnces,1992,83:305.
Bornhorst T J. 1986. Partitioning of gold in young calc-alkaline volcanic rocks from Guatemala. J Geol,94:412~418.
Bowen,N.L., The evolution of the igneous rocks,Princeton. Univ. Press. 1928.
Burnard P G,Hu Ruizhong,Turner G,et al. Mantle,crustal and atmospheric noble gases in Ailaoshan gold deposits,Yunnan province,china.Geochimical et Cosmochimica Acta,1999, 63:1595~1604.
Burnham C W. Magma and hydrothermal fluids. In:Barnes HL ed. Geochemistry of hydrothermal ore deposits. New York:Wiley. 1979,71~136.
Candela P A and Holland H D. The partitioning of copper and molybdenum between silicate melts and squeous fluids.Geochimica et Cosmochimica Acta,1984,48: 373~380.
Candela P A. Controls on ore metal ratios in grante-related oresystems:An experirnental and computatlonal approaeh.Transaetions of the Royal Soeiety of Edinburgh,Earth Seienees,1992,83:317.
Cherniak D J.. Rare-earth diffusion in zircon.Chemical Geology,1997, 134:289.
Clack A H. A reoutside porphyry copper deposits either anatomically or environmentally distinctive?.Soci Econ Geol, 1993,213~283.
Cline J and Bodnar R J. Can economic porphyry copper mineralization be generated by a typical cale-alkaline melt?.Journal of Geophysical Research,1991,96:8113~8126.
Cline J S. Genesis of porphyry copper deposits:the behavior of water,chloride,and copper in crystallizing melts,in Pierce,F W and Bolm,J G,eds.,Porphyry copper deposits of the American Cordillera.Arizona Geological Society Digest,1995,20:69~82.
Collins,W.J.. Nature and origin of A-Type granites with particular reference to south-eastern Australia,Contr. Miner. Petro., 1982,80,189~200.
Cooke D R,Hollings P,and Walshe J L. Giant Porphyry Deposits: Characteristics,distribution, and tectonic controls.Econ.Geol.,2005,100:801~818.
Davidson J P. Deciphering mantle and crustal signatures in subduction zone magmatism. Geophysical Monograph,1996,96:252~262.
Defant M J and Drummond M S. Derivation of some modern arc magmas by melting of young subducted lithosphere. Nature,1990, 347:662~665.
Defant M J,Xu J F,Kepezhinskas P,et al. Adakites:some variations on a theme.Acta Petrologica Sinica,2002, 18:129~142.
Depaolo D J. Neodymium isotopes in geology.Springer-verlag,1988,187.
Dilles J H. Petrology of the yerington Batholith,Nevada:Evidence for evolution of porphyry copper ore fluids. Economic Geology,1987,82:1750~1780.
Faure G. .Principles of Isotope Geology.John Wiley and Sons,1977,464.
Fuex A N,Baker D R. Stable carbon isotopes in selected granitic,mafic,and ultramafic igneous rocks.Geochim.et Cosmochim.Acta,1973,37:2509~2521.
Gustafson L B and Hunt J P. The porphyry copper deposits at El Salvador,Chile. Econ.Geol,1975,70:857~912.
Hacker B R. Evolution of the northern Sierra Nevada metamorphic belt:Petrological. structural and Ar/Ar constraints. Geology Society of America Bulletin. 1993,105:637~656.
Hamlyn P K,Keays R R,Cameron W E,et al. Preciousmetals in magnesian low-Ti lavas: Implications for metallogenesis and sulfur saturation in primarymagmas. Geochim et Cosmochim Acta,1985,49:1797~1811.
Harris A C and Golding S D. New evidence of magmatic-fluid-related phyllic alteration: Implications for the genesis of porphy ry Cu deposits.Geology,2002,30:335~338.
Harris A C,Golding S D,and White N C. Bajo de la Alumbrera copper-gold deposit:Stable isotope evidence for a porphyry-related hydrothermal system dominated by magmatic aqueous fluids.Econ.Geol.,2005,100:863~886.
Harris A C,Kamenetsky V S,White N C,et al.. Volatile Phase separation in silicic magmas at Bajo de la Alumbrera porphyry Cu-Au deposits,NW Argentina.Resource Geology,2004,54:341~356.
Hattori K H and Keith J D. Contribution of mafic melt to porphyry copper mineralization: evidence from Mount Pinatubo , Philippines,andBingham Canyon,Utah,USAJ. Mineralium Deposita,2001,36: 799~806.
Hedenquist J W, Arriba A J, Reynolds T J. Evolution of an intrusion-centered hydrothermal system: Far Southeast-Lepanto porphtyry and epithermal Cu-Au deposits, Philippines. Economic Geology, 1998,93: 373~404.
Hedenquist J W,and Lowenst J B. The role of magmas in formation of hydrothermal ore deposits. Nature,1994,370:519~527.
Heinrich C A,Gunther D, Audetat A,et al. Metal fractionation between magmatic brine and vapor,determined by microanalysis of fluid inclusions. Geology,1999,27:755~758.
Heinrich C A. The physical and chemical evolution of low-Salinity magmatic fluids at the porphyry to epithermal transition:a thermodynamic study.Mineralium Deposita,2005,39:864~889.
Holliday J R,Wilson A J, Blevin P L,et al. Porphyry gold-copper mineralization in the Cadia district,eastern Lachlan Fold Belt,New South Wales,and its relationship to shoshonitic magmatism.Mineralium Deposita,2002,37: 100~116.
Hollister V F,Potter R R,and Barker A L.Porphyry-tyoe deposits of the Appalachian orogen.Econ.Geol.,1974,69:618~630.
Hunt J P. Porphyry copper depositsJ. Econ. Geol.,1991,8:192~206.
Imai A,Listanco E L and FujⅡT. Petrologic and sulfur isotopic significance of highly oxidized and sulfur-rich magma of Mount Pinatubo,Philippines. Geology,1993,21:699~702.
Ishihara S. The granitoid series and mineralization. Economic Geology 75th Anniversary volume, 1981,458~484.
Jugo P J,Luth R W and Richards J P. Generation of sulfur-rich,sulfur-undersaturated basaltic melts in oxidized arc sources.2003 AGU Fall Meeting. 2003.
Kay R W. Aleutian magnesium andesites:melts from subducted Pacific oceanic crust. J.Volcanol. Geotherm.Res.,1978,4:117~132.
Kay S M,Mpodozis C. Central Andean ore deposits linked to evolved shallow seduction systems and thickening crust . 2001,GSA Today,11: 4~9.
Kendrick M A,Burgess R,Pattrick R A D,et al. Halogen and Ar-Ar age determinations of inclusions within quartz veins from porphyry copper deposits using complementary noble gas extraction techniques,Chemical Geology,2001,177:351~370.
Kerrich R,Goldfarb R,Groves D,et al. The characteristics,origins,and geodynamic settings of supergiant gold metallogenic provinces[J]. Science in China(Serials D),2000,43:1~68.
Kilinc I A and Burnham C W. Partioning of chloride between a silicate melt and coexisting aqueous phase from 2 to 8 kilobars. Econ.Geol.,1972,67:231~235.
Lowell J D,Guibert J M. Lateral and vertical alteration-mineralization zoning in porphyry ore deposits.Econ Geal,1970,65:373~408.
Luck J M,Allegre C J. The studies of molybdenites through 187Re-187Os the chronometer. Earth Planet Sci Lett,1982,61:291~296.
Marsh T M,Einaudi M T,Mewilliams M. 40Ar/39Ar geoehronoogy of Cu-Au and Au-Ag mineralization in the Potrerillos district,Chile.Econ Geol,1997,92:784~806.
Martin H. Adakitic magmas:Modern analoguesof Archean granitoidsJ . Lithos,1999, 46: 411~429.
Maughan D T.. 2002. Contributions from mafic alkaline magmas to the Bingham porphyry Cu-Au-Mo deposit,Utah,USA[J].Mineralium Deposita,37:14~37.
Minster J F,Richard L P,Allegre C J,1979. 87Rb-87Sr chronology of enstatite meteorites.Earth Planet Sci lett,44:420~440.
Misra K C. Understanding mineral deposits.Kluwer Academic Publishers,2000. 353~413.
Mitchell A H G. Metallogenic belts and angle of dip of Benioff zones. Nature,1973,245:49~52.
Muller D.. The transition from porphyry to epithermal-style gold mineralization at Ladolam,Lihir Island,Papua NewGuinea:a reconnaissance study.Mineralium Deposita,2002, 37:61~74.
Mungall J E. Roasting the mantle:Slab melting and the genesis of major Au and Au-rich Cu deposits.Geology,2002,30:915~918.
Nagaseki H and Hayashi K. Experimental study of the behavior of copper and zinc in a boiling hydrothermal system.Geology,2008,36:27~30.
Ohmoto H and Goldhaber M B. Sulfur and carbon isotopes. In:Barnes H L ed. Geochemistry of hydrothermal ore deposits. New York:Wiley. 1997,517~611.
Ohmoto H,Rye R O. Isotope of Sulfur and Carbon.In:Geochemistry of Hydrothermal Ore Deposits,John Wiley and Sons,New York. 1979,509~567.
Ohmoto H. Systematics of sulfur and carbon isotopes in hydrothermal ore deposits. Econ Geol,1972,67:551~579
Oyarzun R,Marquez A,Lillo J,et al. Giant versus small porphyry copper deposits of Cenozoic age in northern Chile: adakitic versus normal calc-alkaline magmatism. Mineralium Deposita,2001,36:794~798.
Pearce,J.A.,Harris,N.B.W. and Tindle,A.G., Trace element discrimination diagrams for the tectonic interpretation of granitic rocks,J.Petrol., 1984,25:956~983..
Rapp P R,Shimizu N and Norman M D. Applegate,reaction between slab-derived melt and peridotite in the mantle wedge:Experimental constrains at 3.8 GPa. 1999,Chem. Geol.,160:335~356.
Redmond P B,Einaudi M T,Inan E E,et al. Copper deposition by fluid cooling in intrusion-centered systems:New insights from the Bingham porphyry ore deposit,Utah. Geology,2004,217~230.
Reich M,Parada M A,Palacios C,et al. Adakite-like signature of Late Miocene intrusions at the Los Pelambers giant porphyry copper deposit in theAndes of central Chile: metallogenic implications. Mineralium Deposita,2003, 38:876~885.
Reynoids T J,Beane R E. Evolution of hydrothermal fluid characteristics at the Santa Rita,New Mexico,porphyry copper deposit. Econ Geol,1985,80:1328~1347.
Reynolds,Peter,Ravenhurst,et al. High-precision 40Ar/39Ar dating of two consecutive hydrothermal events in the Chuquicamata porphyry copper system, Chile. Chemical Geology,1998,148:45~60.
Richards J P ang Kerrich R. Adakike-like rocks:Their diverse origins and questionable role in metallogenesis.Economic Geology,2007,102:537~576.
Richards J P,Boyce A J and Pringle M S. Geologic evolution of the Escondida area,northern Chile: a model for spatial and temporal location of porphyry Cu mineralization. Econ. Geol.,2001, 96:271~306.
Richards J P,McCulloch,M T,Chappell,B W,et al. Sourcesof metals in the Porgera gold deposit , PapuaNew Guinea: evidence from alteration , isotope , and noble metal geochemistry.Geochim et Cosmochim Acta,1991,55:565~580.
Richards J P. Tectono-magmatic precursors forporphyryCu-(Mo-Au) deposit formation. Economic Geology,2003,98:1515~1533.
Richards J P. Alkalic-type epithermal gold deposits-a review. Mineralogical Association of Canada Short Course Series,1995,23:367~400.
Richards,J P. Cumulative factors in the generation of giant cale-alkaline porphyry Cu deposits. In Porter T.M.(ed).Super-Porphyry Copper and Gold Deposits:A Global Perspective,PGC Publishng,Adelaide,2005,7~25.
Roddick J C. The application of isochron iagrams in 40Ar-39Ar dating:a discussion. Earth and planetary science letters,1978,41:233~244.
Roedder E. Fluid inclusion studies on the porphyry-type oredeposits at Bingham,Utah,Butte,Montana,and Climax,Colorado. Econ Geol,1971,66:98~120.
Rusk B G,Reed M H,Dilles J H,et al. Compositions of magmatic hydrothermal fluids determined by La-ICP-MS of fluid inclusion from the porphyry copper-molybdenum deposit at Butte,MT.Chemical Geology,2004,210:173~199.
Sajona F G and Maury R C. Association of adakites with gold and copper mineralization in the Philippines. CR. Acad. Sci. Paris,1998,326(1): 27~34.
Selby D,GreaserR A. Re-Os geochronology and systematics in molybdenite from the Endako porphyry molybdenum deposit,British Columbia,Canada. Econ Geol,2001,96:197~204.
Sillitoe R H. A plate tectonic model for the origin of porphyry copper deposits. Econ. Geol.,1972,67:184~197.
Sillitoe R H. Geology of the Los Pelambres porphyry copper deposits,Chile. Econ.Geol. 1973,67:1~10.
Sillitoe R H. Characteristics and controls of the largest porphyry copper-gold and epithermal gold deposits in the circum-Pacific region.Austr Jour Earth Sci,1997,44:373~388.
Sillitoe R H. Epochs of intrusion-related copper mineralization in the Andes.J. S.Am. Earth Sci.,1988,1: 89~108.
Sillitoe, R.H., Some thoughts on gold-rich porphyry copper deposits. Mineralium Deposita, 1979, 14: 161~174.
Sillitoe, R.H. Gold-rich porphyry deposits: Descriptive and genetic models and their role in exploration and discovery. Reviews in Economic Geology, 2000, 13: 315~345.
Simmons S F,Sawkins F J,Schlutter D J. Mantle-derived helium in two Peruvian hydrothermal ore deposits.Nature,1987,329:429~432.
Singer D A ,Berger V I,Menzie W D,et al. Porphyry copper deposit density.Econ.Geol.,2005,100:491~514.
Stein H J,Markey R J,Morgan J W,et al. Highly precise and accurate Re-Os ages formolybdenite from the East Qin ling molybdenite belt,Shaanxi Province,China. Econ Geol,1997,92:827~835.
Stein H J,Sundblad K,Markey R J,et al. Re-Os ages for Archean molybdenite and pyrite,Kuittila-Kiviso,Finland and Proterozoic molybdenite,Kabeliai,Lithuania: testing the chronometer in ametamorphic and metasomatic setting. Mineralium Deposita,1998,33:329~345.
Stern C R and Kilian R. Roleof the subducted slab,mantle wedge and continental crust in the generation of adakites from the AndeanAustral Volcanic Zone. Contril. Mineral. Petrol.,1996,123: 263~281.
Taylor S R and Mclennan S M. The Continental Crust:its Composition and Evolution. London: Biackwell. 1985,57~72.
Thieblemont D,Stein G and Lescuyer J L. Epithermal and por-phyry deposits: the adakite connection. Earth and Planet. Sci.,1997,325:103~109.
Turner G,Burnnard P B,Ford J L,et al. Tracing fluid sources and interaction.Phil Trans R Soc Lond A,1993,344:127~140.
Uyeda S,Kanamori H. Back-arc opening and the model of subduction.Jour Geophys Res,1979,84:1040~1061.
Vila, T. and Sillitoe, R.H., Gold-rich porphyry systems in the Maricunga belt, northern Chile. Economic Geology, 1991a,86: 1238~1260.
Vila, T., Sillitoe, R.H., Betzhold, et al. The porphyry gold deposits at Marte, northern Chile.Economic Geology, 1991b,86: 1271~1286.
Wallace P and Carmicheal I S E. Sulfur in basaltic magmas. Geochim. Cosmochim. Acta,1992,56:1863~1874.
Wan. Rb-Sr geochronology of chalcopyrite from the Chehugou porphyry Mo-Cu deposit (Northeast China) and geochemical constraints on the origin of hosting granites. Economic Geology, 2009,104: 351-363
Watanabe Y,Stein H,Morgan J W,et al. Re-Os geochronobgy brackets tining and duration of mineralization for the EI Salvador porphyry Cu-Mo deposit,Chile(abstract).Geol Soci Am.Abs with Prog,1999,31:A30.
Wood D.A., The application of A Th-Hf-Ta diagram to probiems of tectonomagamatic classification and to establishing the nature of crustal contamination of basaltic lavas of the British Tertiary volcanic province.Earth planet.Sci.Lett., 1980,50,11~30.
Wybon D. Sulphur-undersaturatedmagmatism-a key factor for generatingmagma-related copper-gold deposits.AGSO Research News letter,1994,21:7~8.
Batchelor,R.A..利用多阳离子参数对花岗岩系作成因解释,基础地质译丛,1986,(4):36~45,61.
Bowden,P..花岗质岩石分类的岩石学、地球化学和来源准则讨论,国外花岗岩类地质与矿产,1986,(2):1~9.
Hugh R. Rollison著,杨学明,杨晓勇,陈双喜译,岩石地球化学,安徽.合肥:中国科学技术大学出版社,2000.
白文吉,杨经绥,胡旭峰,等.内蒙古贺根山蛇绿岩岩石成因和地壳增生的地球化学制约.岩石学报, 1995,11(增):111~123.
包志伟,陈森煌,张祯堂.内蒙古贺根山地区蛇绿岩稀土元素和Sm-Nd同位素研究.地球化学, 1994,23(4):339~349
毕力赫金矿.内蒙古自治区苏尼特右旗毕力赫金矿勘探地质报告,1993.
曹生儒.对内蒙古古板块构造轮廓的新认识.中国区域地质, 1993,(3):211~215
常印佛,刘湘培,吴言昌.长江中下游铜铁乘矿带.北京:地质出版社,1991
陈昌勇.华北地块北缘金矿床类型及成矿系列.辽宁地质,1998,(3):214~223.
陈骏,王鹤年主编,地球化学,北京:科学出版社,2004.
陈崎,仇甘霖,杜玉申,等.白乃庙—温都尔庙区域构造及华北北缘古板块构造演化.长春地质学院学报,1992,(22):119~129.
方曙,鞠文信,张亚盾.内蒙古东南部中生代构造应力场的多次转换及动力机制探讨.地质力学学报, 2002,8(1):26~35.
高计元,王一先,裘愉卓,等.内蒙古中西部多岛海构造演化.大地构造与成矿学, 2001,25(4):397~404.
高晓峰,郭峰,范蔚茗,等.南兴安岭晚中生代中酸性火山岩的岩石成因.岩石学报, 2005,21:737~748.
葛良胜,卿敏,侯增谦,等,内蒙古毕力赫大型金矿勘查突破过程及启示意义,矿床地质,2009,28(4):390~402.
葛良胜,卿敏,袁士松,等,危机矿山接替资源勘查的理论、技术与思路—以内蒙古毕力赫金矿勘查突破为例,矿物学报,2007,27(增):503~505.
葛良胜,卿敏,张文钊,等,华北板块北缘首例大型高品位隐伏斑岩型金矿床——内蒙古毕力赫金矿,中国地质,2009,(10):1110~1122.
葛良胜,王文成,李汉光,等.滇西北富碱岩体与金矿成矿.北京:地震出版社. 2005.
葛良胜,邹依林,李振华,等.云南马厂箐(铜、钼)金矿床地质特征及成因研究.地质与勘探,2002,38(5):11~17.
葛良胜.滇西北富碱岩浆活动与金多金属成矿系统(博士学位论文).北京:中国地质大学(北京),2007.
葛良胜,张文钊,袁士松,等,蒙古南戈壁-中国东乌旗跨国境成矿带东段金多金属矿床成矿与找矿,北京:地质出版社. 2009.
郭峰,范蔚茗,王岳军,等.大兴安岭南段晚中生代双峰式火山作用.岩石学报, 2001,17: 161~168.
郭胜哲.1986.中朝板块与西伯利亚板块拼合时限的确定及其生物地层学依据[J].沈阳地质矿产研究所所刊,( 14 ) :127~136
何国琦,李茂松.兴蒙-北疆及邻区古生代蛇绿岩的对比研究及其大地构造意义,见:张旗主编.蛇绿岩与地球动力学研究.北京:地质出版社, 1995,104~107.
和钟铧,梁一鸿.内蒙古白乃庙金矿断裂构造控矿研究.地质与勘探,2001,37(2):28~32.
洪大卫,黄怀曾,肖宜君,等.内蒙古中部二叠纪碱性花岗岩及其地球动力学意义.地质学报, 1994,68:219~230.
洪大卫,王式光,谢锡林,等.兴蒙造山带正ε(Nd,t)值花岗岩的成因和大陆地壳生长.地学前缘, 2000,7(2):441~455.
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.矿床地质,2003,22(1):1~12.
侯增谦,潘小菲,杨志明,等.初论大陆环境斑岩铜矿.现代地质,2007,21(2):332~351.
侯增谦.斑岩Cu-Mo-Au矿床:新认识与新进展.地学前缘,2004, 11(1):131~144.
胡家富,张中杰,张慧,等.中国内蒙古高原及周边地带岩石圈三维速度结构.地球物理学进展, 1996,11(4):20~33.
胡朋,聂凤军,江思宏,等.南蒙古典型金属矿床地质特征及结中国相邻地区的找矿启示.矿床地质, 2006.25(增):123~126.
胡骁,许传诗,牛树银.华北地台北缘早古生代大陆边缘演化.北京:北京大学出版社, 1990.6~24.
黄汲清,任纪舜,姜春发,等.中国大地构造及其演化.北京:科学出版社.1980.
贾和义,宝音乌力吉,张玉清.内蒙古达茂旗乌德缝合带特征及大地构造意义同.成矿理工大学学报(自然科学版), 2003.30(1):30~34.
蒋少涌,杨竟红.金属矿床Re-Os同位素示踪与定年研究.南京大学学报(自科版). 2000.
睢程晨.内蒙古自治区毕力赫金矿蚀变和流体包裹体特征分析(硕士学位论文).北京:中国地质大学(北京),2009.
冷福荣,刘旺盛,苏英.1996.华北地台北缘海西期花岗岩类地球化学特征及构造环境探讨[J].内蒙古地质,18-25
李继宏,张万昌.2005.内蒙古东乌旗草原覆盖区遥感构造信息提取[J].地质找矿论丛,20(2):137-142
李述靖,张维杰,耿明山等.1998.蒙古弧地质构造特征及形成演化概论[M].北京:地质出版社
李双庆.1997.内蒙古中部早古生代地体的拼合与增置[J].内蒙古地质,84(1):18-23
李思田,杨世恭. 1987.中国东北部中生代裂陷作用和东北亚断陷盆地[J].中国科学(B辑), 21: 185~195.
李晓勇,郭锋,王岳军.2002.造山后构造岩浆作用研究评述[J].高校地质学报,8(1):68-77
里特曼著,金秉慧译,1979,火成岩的稳定组合计算方法,地质出版社
李颖,刘连登.斑岩型金矿的概念及相关问题讨论.世界地质,1999,18(1):16-22.
梁华英. 2002.玉龙斑岩铜矿带的锆石SHRMP年龄[C].中国基础研究项目报告.
梁日暄.1994.内蒙古中段蛇绿岩特征及地质意义[J].中国区域地质,(1):37-45
梁一鸿,张宏颖.2000.内蒙古中部含金建造的形成环境[J].黄金,21(12):5-9
刘红涛,张旗,刘建明,等. 2004.埃达克岩与Cu-Au成矿作用有待深入研究的岩浆成矿关系[J].岩石学报,20(2): 205~218.
刘益康,徐叶兵.2003.蒙古OyuTolgoi斑岩铜金矿的勘查[J].地质与勘探,39(1):1-4
刘玉强.1994.内蒙古东部晚中生代断陷煤盆地与伸展构造[J].矿床地质,13(3):212-220
刘正宏,刘雅琴,冯本智.2004.华北板块北缘中元古代造山带的确立及其构造演化[J].长春科技大学学报,30(2):110-114
卢造勋,夏怀宽.1992.内蒙古东乌珠穆沁旗-辽宁东沟地学断面[J].地球物理学报,35 (6):765-772
罗飞,罗照华,李述靖等.1995.内蒙古中部白至纪碱性花岗岩的发现及意义[J].现代地质,9(2):203-212
罗飞.1995.内蒙古中部白至纪碱性花岗岩的发现及意义[J].现代地质,9(2):203-211
孟庆任,胡健民,袁选俊,靳久强. 2002.中蒙边界地区晚中生代伸展盆地的结构、演化和成因[J].地质通报, 21:224~231.
内蒙古自治区地质矿产局.1991.内蒙古自治区区域地质志[M].北京:地质出版社
内蒙古自治区地质矿产局.1996.内蒙古自治区岩石地层[M].武汉:中国地质大学出版社
内蒙古自治区第四地质矿产勘查开发院.内蒙古自治区苏尼特右旗毕力赫金矿增储(详查)地质报告,1998
聂凤军,江思宏,张义等.2004.中蒙边境及邻区斑岩型铜矿床地质特征及成因[J].矿床地质,23(2):176-190
聂凤军,江思宏,张义等.2007.中蒙边境中东段金属矿床成矿规律和找矿方向[M].北京:地质出版社
聂凤军,江思宏,赵省民,2000.斑岩型铜金矿床研究新进展[J].内蒙古地质,2(总第95期):1-11
聂凤军,裴荣富,吴良士等.1993.内蒙古白乃庙地区岩浆活动与金属成矿作用[M].北京:北京科学技术出版社
聂凤军,张义,江思宏.2003.中蒙边境中东段我国一侧(北山和二连_东乌旗地区)铜金银矿床成矿规律与找矿方向[A].中国地质调查局地质调查项目技术报告(内部资料)[R],1-14
钱青. 2001. adakite的地球化学特征及成因[J].岩石矿物学杂志,20(3):297~306.
邱家骧,1991,应用岩浆岩岩石学,湖北.武汉,中国地质大学出版社.
邱家骧,1983,火山岩的成分与板块构造环境,地质科技情报,第1期,6-16.
芮宗瑶,黄崇轲,齐国明,等. 1984.中国斑岩型铜(钼)矿[M].北京:地质出版社.
尚恒胜,陶继雄,宝音乌力吉等.2003.内蒙古白云鄂博地区早古生代弧-盆体系及其构造意义[J].地质调查与研究,26(3):160-168
邵积东.1998.内蒙古大地构造分区及其特征[J].内蒙古地质,(2):1-23
邵济安,韩庆军.2000.内蒙古东部早中生代壳慢过渡带—捕虏体岩石高温高压下弹性波速度实验证据[J].中国科学(D辑),30(增):154-160
邵济安,洪大卫,张履桥.2002.内蒙古火成岩Sr-Nd同位素特征及成因[J].地质通报,21(12):817-822
邵济安,刘福田,陈辉等.2001.大兴安岭-燕山中生代岩浆活动与俯冲作用关系[J].地质学报,75(4):56-63
邵济安,唐克东.1995.蛇绿岩与南蒙古洋的演化,见张旗主编,蛇绿岩与地球动力学研究[M].北京:地质出版社,117-120
邵济安,张履桥,牟保磊.1999.大兴安岭中生代伸展造山过程中的岩浆作用[J].地学前缘,6(4):339-346
邵济安.1991.中朝板块北缘中段地壳演化,北京:北京大学出版社,11-91
沈存利,苏宏伟,王守光.2004.内蒙古铜矿床区域成矿特征初步研究[J].西北地质,37(3):43-50
唐克东,张允平.1991.内蒙古缝合带的构造演化,见:肖序常,汤粗庆主编古中亚夏合巨型缝合带南缘构造演化[M].北京:北京科学技术出版社,30-54
唐克东.1989.中朝陆台北侧褶皱带构造发展的几个问题[J].现代地质,3(2):195-204,
唐克东.1992.中朝板块北侧褶皱带构造演化及成矿规律[M].北京:北京大学出版社,60-179,223-242
唐纳.W.海因德曼著,邱家骧,王人镜,马昌前译,火成岩与变质岩岩石学,湖北武汉:中国地质大学出版社,1989.
陶继雄,胡凤翔,陈志勇.2003.华北陆块北缘印支期S型花岗岩带特征及其构造环境[J].岩石矿物学杂志,22(2):112-118
滕吉文.2007.地壳内部金属矿产聚集的深层动力过程与兴、蒙成矿域找矿探查的战略意义[A],全国深部找矿工作会议[C],安徽合肥,9,26-29
涂光炽. 1989.关于富碱侵入岩[J].矿产与地质,13(3):1.
涂光炽等.2000.中国超大型矿床[M].北京:科学出版社,397-425
王荃.1986.内蒙古中部中朝与西伯利亚古板块间缝合线的确定[J].地质学报,1:31-43
王瑞廷,欧阳建平,蒋敬业.1999.内蒙古东部半干旱草原残丘景观区铜多金属元素表生地球化学异常特征及其评价指标体系的构建[J].矿产与地质,13(6):348-13
王瑜.1994.中国东部内蒙燕山地区晚古生代晚期-中生代的造山作用过程[D].北京:中国地质科学研究院
王瑜.1996.晚古生代末-中生代内蒙古燕山地区造山过程中的岩浆热事件与构造演化[J].现代地质,10(1):66-75
王玉净,樊志勇.1997.内蒙古西拉木伦河北部蛇绿岩带中二叠纪放射虫的发现及其地质意义[J].古生物学报,36(1):58-69
王喻.1996.中国东部内蒙古造山带晚古生代晚期-中生代的造山作用过程[M].北京:地质出版社
王喻.1998.中生代以来华北地区造山带与盆地的演化及动力学[M].北京:地质出版社
王元龙,张旗,王强,等. 2003.埃达克质岩与Cu-Au成矿作用关系的初步探讨[J].岩石学报,19:543~550.
王肇芬,赵俊磊,王璞译.1990.世界斑岩铜矿.北京:地质出版社.
吴泰然,张臣,万基虎.1998.内蒙古温都尔庙地区温都尔庙群的形成环境和构造意义[J].高校地质学报,4(2):168-176
武警黄金地质研究所.内蒙古自治区苏尼特右旗毕力赫金矿区Ⅱ矿带15-40线详查报告,2008.8
肖成东,付国立,赵利青.2000.内蒙古锡盟—赤峰北部板块构造演化与金矿床[J].黄金地质,6(2):17-20
肖荣阁,隋德才,罗照华等.1995内蒙古北部早元古代变质岩系的发现及其岩石学研究[J].现代地质,9(2):142-148
徐备,J,Charvet,张福勤.2001.内蒙古北部苏尼特左旗蓝片岩岩石学和年代学研究[J].地质科学,36(4):424-434
徐备,陈斌,张巨等.1994.华北板块北缘中段含铁变质岩系的时代和构造环境初探[J].地质论评, 40(4):307-311
徐备,陈斌.1997.内蒙古北部华北板块与西伯利亚板块之间中古生代造山带的结构及演化[J].中国科学(D辑),27(3):227-232
徐备.1998.内蒙古北部温都尔庙群北带沉积环境及构造意义[J].,Scientia geologica sinica,33(4):406-411
徐备.1998.内蒙古北部温都尔庙群北带沉积环境及构造意义[J].地质科学,33(4):406-411
徐备.2001.内蒙古北部苏尼特左旗蓝片岩岩石学和年代学研究[J].地质科学,36(4):424-434
许立权,邓晋福,陈志勇.2004.内蒙古中部印支期强过铝质花岗岩的相平衡约束及动力学背景[J].地质通报,23(8):790-794
许立权,邓晋福,陈志勇.2004.内蒙古中部印支期强过铝质花岗岩的相平衡约束及动力学背景[J].地质通报,23(8):790-794
许立权,贾和义,张玉清等.2004.白云鄂博地区碱性正长岩特征及其意义[J].地质调查与研究,27(1):43-47
许立权.2004.内蒙古中部印支期强过铝质花岗岩的相平衡约束及动力学背景[J].地质通报,23(8):790-794
薛重生.1997.遥感技术在区域地质调查中的应用研究进展[J].地质科技情报,16(增):16-22
杨志明,侯增谦,李振清,宋玉财,谢玉玲. 2008.西藏驱龙斑岩铜钼矿床中UST石英的发现:初始岩浆流体的直接记录[J].矿床地质, 27: 188~199.
冶金工业部地质研究所.1984.中国斑岩铜矿.北京:科学出版社.
翟安民,李增慧,汪玉麟等.1981.内蒙古包日汗区温都尔庙群变质岩系的构造演化特点[J].中国地质科学院院报,3(1):21-31
翟裕生,林新多. 1993.矿田构造学.北京:地质出版社
翟裕生,邓军,王建平等,深部找矿问题研究,矿床地质,2004,23(2):142-149
翟裕生,彭润民,向运川,等.2004.区域成矿研究法[M].北京:中国大地出版社.
翟裕生.论成矿系统.地学前缘,1999,1.
张旗,王焰,刘伟,等. 2002.埃达克岩的特征及其意义[J].地质通报,21:431~435.
张旗,许继峰,王焰,等. 2004.埃达克岩的多样性[J].地质通报,23(9-10):959~965.
张臣,吴泰然.1998.内蒙古温都尔庙群变质基性火山岩Sm-Nd、Rb-Sr同位素年代研究[J].地质科学,33(1):25-30
张臣,吴泰然.1999.内蒙古苏左旗南部早古生代蛇绿混杂岩特征及其构造意义[J].地质科学,34(3):381-389
张臣,吴泰然.1999.内蒙古苏左旗南部早古生代蛇绿混杂岩特征及其构造意义[J].地质科学,34(3):381—389
张臣,吴泰然.2001.内蒙古苏左旗南部华北板块北缘中新元古代-古生代裂解-汇聚事件的地质记录[J].岩石学报,17(2):199-205
张臣.1999.内蒙古苏左旗南部温都尔庙群地层研究的新进展[J].地学前缘,6(3):112
张义,聂凤军,江思宏.2003.中蒙边境欧玉陶勒盖大型铜-金矿床的发现及对找矿勘查工作的启示[J].地质通报,22(9):708-712
张义,聂凤军,孙彬彬等.2005.内蒙古中东部浅覆盖区化探岩屑测量方法研究及靶区优选应用[J].中国地质,32(4):696-705
张振法,葛昌宝.2000.内蒙古东部区深部构造特征和大地构造问题浅议[J].内蒙古地质,(3):6-13
张振法.1990.显生宙蒙古洋地球动力学环境及有关问题探讨[J].地质科技情报,3
张振法.1993.西伯利亚板块和中朝板块间古地球动力学环境及两大板块中段缝合位置[J].地质科技情报,1
张振法.1994.根据深部地球物理资料和古板块构造格架重新厘定槽台界线[J].内蒙古地质,1-15
中国北方板块构造论文集编委会.1986.中国北方板块构造论文集(第一集) [C].北京:地质出版社
中国北方板块构造论文集编委会.1987.中国北方板块构造论文集(第二集) [C].北京:地质出版社
中国科学院矿床地球化学开放研究实验室,矿床地球化学[M].北京:地质出版社,1997
朱英等.2004.中国及邻区大地构造和深部构造纲要[M].北京:地质出版社
朱永锋,孙世华,毛骞,赵光. 2004.内蒙古锡林格勒杂岩的地球化学研究:从Rodinia聚合
到古亚洲洋闭合后碰撞造山的历史记录[J].高校地质学报, 10: 343~355.
Ballard J R..Two age of porphyry intrusion resolved for the super-giant Chuquieamata copper deposit of northern Chile by ELA-ICP-MS and SHRIMP. Geology,2001,29(5):383.
Baptiste P J,Fouquet Y. Abundance and isotopic composition of helium in hydrothermal sulfides from the East Pacific Rise at 13N. Geochim Acta,1996,60:87~93.
Barra F,Ruiz J,Mathur R,Titley S. A Re-Os study of sulfide and minerals from the Bagdad porphyry Cu-Mo deposit,northern Arizona,USA. Mineralium Deposita,2003,38:585~596.
Beane R E and Titley S R. Porphyry copper deposits:PartⅡ.Hydrothermal alteration and mineralization.Econmic Geology 75th Anniversary Volume,1981,235~263.
Bellon H,Yumul Jr G P. Miocene to Quaternary adakites and related rocks in western Philippine arc sequences. Earth and Planetary Sciences. 2001,333: 343~350.
Blevln P L..The role of magma sourees,oxldation states and fraetzonation in determining the granlte metallogeny of eastern Australla.Transaetions of the Royal Soeiety of Edinburgh,Earth scicnces,1992,83:305.
Bornhorst T J. 1986. Partitioning of gold in young calc-alkaline volcanic rocks from Guatemala. J Geol,94:412~418.
Bowen,N.L., The evolution of the igneous rocks,Princeton. Univ. Press. 1928.
Burnard P G,Hu Ruizhong,Turner G,et al. Mantle,crustal and atmospheric noble gases in Ailaoshan gold deposits,Yunnan province,china.Geochimical et Cosmochimica Acta,1999, 63:1595~1604.
Burnham C W. Magma and hydrothermal fluids. In:Barnes HL ed. Geochemistry of hydrothermal ore deposits. New York:Wiley. 1979,71~136.
Candela P A and Holland H D. The partitioning of copper and molybdenum between silicate melts and squeous fluids.Geochimica et Cosmochimica Acta,1984,48: 373~380.
Candela P A. Controls on ore metal ratios in grante-related oresystems:An experirnental and computatlonal approaeh.Transaetions of the Royal Soeiety of Edinburgh,Earth Seienees,1992,83:317.
Cherniak D J.. Rare-earth diffusion in zircon.Chemical Geology,1997, 134:289.
Clack A H. A reoutside porphyry copper deposits either anatomically or environmentally distinctive?.Soci Econ Geol, 1993,213~283.
Cline J and Bodnar R J. Can economic porphyry copper mineralization be generated by a typical cale-alkaline melt?.Journal of Geophysical Research,1991,96:8113~8126.
Cline J S. Genesis of porphyry copper deposits:the behavior of water,chloride,and copper in crystallizing melts,in Pierce,F W and Bolm,J G,eds.,Porphyry copper deposits of the American Cordillera.Arizona Geological Society Digest,1995,20:69~82.
Collins,W.J.. Nature and origin of A-Type granites with particular reference to south-eastern Australia,Contr. Miner. Petro., 1982,80,189~200.
Cooke D R,Hollings P,and Walshe J L. Giant Porphyry Deposits: Characteristics,distribution, and tectonic controls.Econ.Geol.,2005,100:801~818.
Davidson J P. Deciphering mantle and crustal signatures in subduction zone magmatism. Geophysical Monograph,1996,96:252~262.
Defant M J and Drummond M S. Derivation of some modern arc magmas by melting of young subducted lithosphere. Nature,1990, 347:662~665.
Defant M J,Xu J F,Kepezhinskas P,et al. Adakites:some variations on a theme.Acta Petrologica Sinica,2002, 18:129~142.
Depaolo D J. Neodymium isotopes in geology.Springer-verlag,1988,187.
Dilles J H. Petrology of the yerington Batholith,Nevada:Evidence for evolution of porphyry copper ore fluids. Economic Geology,1987,82:1750~1780.
Faure G. .Principles of Isotope Geology.John Wiley and Sons,1977,464.
Fuex A N,Baker D R. Stable carbon isotopes in selected granitic,mafic,and ultramafic igneous rocks.Geochim.et Cosmochim.Acta,1973,37:2509~2521.
Gustafson L B and Hunt J P. The porphyry copper deposits at El Salvador,Chile. Econ.Geol,1975,70:857~912.
Hacker B R. Evolution of the northern Sierra Nevada metamorphic belt:Petrological. structural and Ar/Ar constraints. Geology Society of America Bulletin. 1993,105:637~656.
Hamlyn P K,Keays R R,Cameron W E,et al. Preciousmetals in magnesian low-Ti lavas: Implications for metallogenesis and sulfur saturation in primarymagmas. Geochim et Cosmochim Acta,1985,49:1797~1811.
Harris A C and Golding S D. New evidence of magmatic-fluid-related phyllic alteration: Implications for the genesis of porphy ry Cu deposits.Geology,2002,30:335~338.
Harris A C,Golding S D,and White N C. Bajo de la Alumbrera copper-gold deposit:Stable isotope evidence for a porphyry-related hydrothermal system dominated by magmatic aqueous fluids.Econ.Geol.,2005,100:863~886.
Harris A C,Kamenetsky V S,White N C,et al.. Volatile Phase separation in silicic magmas at Bajo de la Alumbrera porphyry Cu-Au deposits,NW Argentina.Resource Geology,2004,54:341~356.
Hattori K H and Keith J D. Contribution of mafic melt to porphyry copper mineralization: evidence from Mount Pinatubo , Philippines,andBingham Canyon,Utah,USAJ. Mineralium Deposita,2001,36: 799~806.
Hedenquist J W, Arriba A J, Reynolds T J. Evolution of an intrusion-centered hydrothermal system: Far Southeast-Lepanto porphtyry and epithermal Cu-Au deposits, Philippines. Economic Geology, 1998,93: 373~404.
Hedenquist J W,and Lowenst J B. The role of magmas in formation of hydrothermal ore deposits. Nature,1994,370:519~527.
Heinrich C A,Gunther D, Audetat A,et al. Metal fractionation between magmatic brine and vapor,determined by microanalysis of fluid inclusions. Geology,1999,27:755~758.
Heinrich C A. The physical and chemical evolution of low-Salinity magmatic fluids at the porphyry to epithermal transition:a thermodynamic study.Mineralium Deposita,2005,39:864~889.
Holliday J R,Wilson A J, Blevin P L,et al. Porphyry gold-copper mineralization in the Cadia district,eastern Lachlan Fold Belt,New South Wales,and its relationship to shoshonitic magmatism.Mineralium Deposita,2002,37: 100~116.
Hollister V F,Potter R R,and Barker A L.Porphyry-tyoe deposits of the Appalachian orogen.Econ.Geol.,1974,69:618~630.
Hunt J P. Porphyry copper depositsJ. Econ. Geol.,1991,8:192~206.
Imai A,Listanco E L and FujⅡT. Petrologic and sulfur isotopic significance of highly oxidized and sulfur-rich magma of Mount Pinatubo,Philippines. Geology,1993,21:699~702.
Ishihara S. The granitoid series and mineralization. Economic Geology 75th Anniversary volume, 1981,458~484.
Jugo P J,Luth R W and Richards J P. Generation of sulfur-rich,sulfur-undersaturated basaltic melts in oxidized arc sources.2003 AGU Fall Meeting. 2003.
Kay R W. Aleutian magnesium andesites:melts from subducted Pacific oceanic crust. J.Volcanol. Geotherm.Res.,1978,4:117~132.
Kay S M,Mpodozis C. Central Andean ore deposits linked to evolved shallow seduction systems and thickening crust . 2001,GSA Today,11: 4~9.
Kendrick M A,Burgess R,Pattrick R A D,et al. Halogen and Ar-Ar age determinations of inclusions within quartz veins from porphyry copper deposits using complementary noble gas extraction techniques,Chemical Geology,2001,177:351~370.
Kerrich R,Goldfarb R,Groves D,et al. The characteristics,origins,and geodynamic settings of supergiant gold metallogenic provinces[J]. Science in China(Serials D),2000,43:1~68.
Kilinc I A and Burnham C W. Partioning of chloride between a silicate melt and coexisting aqueous phase from 2 to 8 kilobars. Econ.Geol.,1972,67:231~235.
Lowell J D,Guibert J M. Lateral and vertical alteration-mineralization zoning in porphyry ore deposits.Econ Geal,1970,65:373~408.
Luck J M,Allegre C J. The studies of molybdenites through 187Re-187Os the chronometer. Earth Planet Sci Lett,1982,61:291~296.
Marsh T M,Einaudi M T,Mewilliams M. 40Ar/39Ar geoehronoogy of Cu-Au and Au-Ag mineralization in the Potrerillos district,Chile.Econ Geol,1997,92:784~806.
Martin H. Adakitic magmas:Modern analoguesof Archean granitoidsJ . Lithos,1999, 46: 411~429.
Maughan D T.. 2002. Contributions from mafic alkaline magmas to the Bingham porphyry Cu-Au-Mo deposit,Utah,USA[J].Mineralium Deposita,37:14~37.
Minster J F,Richard L P,Allegre C J,1979. 87Rb-87Sr chronology of enstatite meteorites.Earth Planet Sci lett,44:420~440.
Misra K C. Understanding mineral deposits.Kluwer Academic Publishers,2000. 353~413.
Mitchell A H G. Metallogenic belts and angle of dip of Benioff zones. Nature,1973,245:49~52.
Muller D.. The transition from porphyry to epithermal-style gold mineralization at Ladolam,Lihir Island,Papua NewGuinea:a reconnaissance study.Mineralium Deposita,2002, 37:61~74.
Mungall J E. Roasting the mantle:Slab melting and the genesis of major Au and Au-rich Cu deposits.Geology,2002,30:915~918.
Nagaseki H and Hayashi K. Experimental study of the behavior of copper and zinc in a boiling hydrothermal system.Geology,2008,36:27~30.
Ohmoto H and Goldhaber M B. Sulfur and carbon isotopes. In:Barnes H L ed. Geochemistry of hydrothermal ore deposits. New York:Wiley. 1997,517~611.
Ohmoto H,Rye R O. Isotope of Sulfur and Carbon.In:Geochemistry of Hydrothermal Ore Deposits,John Wiley and Sons,New York. 1979,509~567.
Ohmoto H. Systematics of sulfur and carbon isotopes in hydrothermal ore deposits. Econ Geol,1972,67:551~579
Oyarzun R,Marquez A,Lillo J,et al. Giant versus small porphyry copper deposits of Cenozoic age in northern Chile: adakitic versus normal calc-alkaline magmatism. Mineralium Deposita,2001,36:794~798.
Pearce,J.A.,Harris,N.B.W. and Tindle,A.G., Trace element discrimination diagrams for the tectonic interpretation of granitic rocks,J.Petrol., 1984,25:956~983..
Rapp P R,Shimizu N and Norman M D. Applegate,reaction between slab-derived melt and peridotite in the mantle wedge:Experimental constrains at 3.8 GPa. 1999,Chem. Geol.,160:335~356.
Redmond P B,Einaudi M T,Inan E E,et al. Copper deposition by fluid cooling in intrusion-centered systems:New insights from the Bingham porphyry ore deposit,Utah. Geology,2004,217~230.
Reich M,Parada M A,Palacios C,et al. Adakite-like signature of Late Miocene intrusions at the Los Pelambers giant porphyry copper deposit in theAndes of central Chile: metallogenic implications. Mineralium Deposita,2003, 38:876~885.
Reynoids T J,Beane R E. Evolution of hydrothermal fluid characteristics at the Santa Rita,New Mexico,porphyry copper deposit. Econ Geol,1985,80:1328~1347.
Reynolds,Peter,Ravenhurst,et al. High-precision 40Ar/39Ar dating of two consecutive hydrothermal events in the Chuquicamata porphyry copper system, Chile. Chemical Geology,1998,148:45~60.
Richards J P ang Kerrich R. Adakike-like rocks:Their diverse origins and questionable role in metallogenesis.Economic Geology,2007,102:537~576.
Richards J P,Boyce A J and Pringle M S. Geologic evolution of the Escondida area,northern Chile: a model for spatial and temporal location of porphyry Cu mineralization. Econ. Geol.,2001, 96:271~306.
Richards J P,McCulloch,M T,Chappell,B W,et al. Sourcesof metals in the Porgera gold deposit , PapuaNew Guinea: evidence from alteration , isotope , and noble metal geochemistry.Geochim et Cosmochim Acta,1991,55:565~580.
Richards J P. Tectono-magmatic precursors forporphyryCu-(Mo-Au) deposit formation. Economic Geology,2003,98:1515~1533.
Richards J P. Alkalic-type epithermal gold deposits-a review. Mineralogical Association of Canada Short Course Series,1995,23:367~400.
Richards,J P. Cumulative factors in the generation of giant cale-alkaline porphyry Cu deposits. In Porter T.M.(ed).Super-Porphyry Copper and Gold Deposits:A Global Perspective,PGC Publishng,Adelaide,2005,7~25.
Roddick J C. The application of isochron iagrams in 40Ar-39Ar dating:a discussion. Earth and planetary science letters,1978,41:233~244.
Roedder E. Fluid inclusion studies on the porphyry-type oredeposits at Bingham,Utah,Butte,Montana,and Climax,Colorado. Econ Geol,1971,66:98~120.
Rusk B G,Reed M H,Dilles J H,et al. Compositions of magmatic hydrothermal fluids determined by La-ICP-MS of fluid inclusion from the porphyry copper-molybdenum deposit at Butte,MT.Chemical Geology,2004,210:173~199.
Sajona F G and Maury R C. Association of adakites with gold and copper mineralization in the Philippines. CR. Acad. Sci. Paris,1998,326(1): 27~34.
Selby D,GreaserR A. Re-Os geochronology and systematics in molybdenite from the Endako porphyry molybdenum deposit,British Columbia,Canada. Econ Geol,2001,96:197~204.
Sillitoe R H. A plate tectonic model for the origin of porphyry copper deposits. Econ. Geol.,1972,67:184~197.
Sillitoe R H. Geology of the Los Pelambres porphyry copper deposits,Chile. Econ.Geol. 1973,67:1~10.
Sillitoe R H. Characteristics and controls of the largest porphyry copper-gold and epithermal gold deposits in the circum-Pacific region.Austr Jour Earth Sci,1997,44:373~388.
Sillitoe R H. Epochs of intrusion-related copper mineralization in the Andes.J. S.Am. Earth Sci.,1988,1: 89~108.
Sillitoe, R.H., Some thoughts on gold-rich porphyry copper deposits. Mineralium Deposita, 1979, 14: 161~174.
Sillitoe, R.H. Gold-rich porphyry deposits: Descriptive and genetic models and their role in exploration and discovery. Reviews in Economic Geology, 2000, 13: 315~345.
Simmons S F,Sawkins F J,Schlutter D J. Mantle-derived helium in two Peruvian hydrothermal ore deposits.Nature,1987,329:429~432.
Singer D A ,Berger V I,Menzie W D,et al. Porphyry copper deposit density.Econ.Geol.,2005,100:491~514.
Stein H J,Markey R J,Morgan J W,et al. Highly precise and accurate Re-Os ages formolybdenite from the East Qin ling molybdenite belt,Shaanxi Province,China. Econ Geol,1997,92:827~835.
Stein H J,Sundblad K,Markey R J,et al. Re-Os ages for Archean molybdenite and pyrite,Kuittila-Kiviso,Finland and Proterozoic molybdenite,Kabeliai,Lithuania: testing the chronometer in ametamorphic and metasomatic setting. Mineralium Deposita,1998,33:329~345.
Stern C R and Kilian R. Roleof the subducted slab,mantle wedge and continental crust in the generation of adakites from the AndeanAustral Volcanic Zone. Contril. Mineral. Petrol.,1996,123: 263~281.
Taylor S R and Mclennan S M. The Continental Crust:its Composition and Evolution. London: Biackwell. 1985,57~72.
Thieblemont D,Stein G and Lescuyer J L. Epithermal and por-phyry deposits: the adakite connection. Earth and Planet. Sci.,1997,325:103~109.
Turner G,Burnnard P B,Ford J L,et al. Tracing fluid sources and interaction.Phil Trans R Soc Lond A,1993,344:127~140.
Uyeda S,Kanamori H. Back-arc opening and the model of subduction.Jour Geophys Res,1979,84:1040~1061.
Vila, T. and Sillitoe, R.H., Gold-rich porphyry systems in the Maricunga belt, northern Chile. Economic Geology, 1991a,86: 1238~1260.
Vila, T., Sillitoe, R.H., Betzhold, et al. The porphyry gold deposits at Marte, northern Chile.Economic Geology, 1991b,86: 1271~1286.
Wallace P and Carmicheal I S E. Sulfur in basaltic magmas. Geochim. Cosmochim. Acta,1992,56:1863~1874.
Wan. Rb-Sr geochronology of chalcopyrite from the Chehugou porphyry Mo-Cu deposit (Northeast China) and geochemical constraints on the origin of hosting granites. Economic Geology, 2009,104: 351-363
Watanabe Y,Stein H,Morgan J W,et al. Re-Os geochronobgy brackets tining and duration of mineralization for the EI Salvador porphyry Cu-Mo deposit,Chile(abstract).Geol Soci Am.Abs with Prog,1999,31:A30.
Wood D.A., The application of A Th-Hf-Ta diagram to probiems of tectonomagamatic classification and to establishing the nature of crustal contamination of basaltic lavas of the British Tertiary volcanic province.Earth planet.Sci.Lett., 1980,50,11~30.
Wybon D. Sulphur-undersaturatedmagmatism-a key factor for generatingmagma-related copper-gold deposits.AGSO Research News letter,1994,21:7~8.
Batchelor,R.A..利用多阳离子参数对花岗岩系作成因解释,基础地质译丛,1986,(4):36~45,61.
Bowden,P..花岗质岩石分类的岩石学、地球化学和来源准则讨论,国外花岗岩类地质与矿产,1986,(2):1~9.
Hugh R. Rollison著,杨学明,杨晓勇,陈双喜译,岩石地球化学,安徽.合肥:中国科学技术大学出版社,2000.
白文吉,杨经绥,胡旭峰,等.内蒙古贺根山蛇绿岩岩石成因和地壳增生的地球化学制约.岩石学报, 1995,11(增):111~123.
包志伟,陈森煌,张祯堂.内蒙古贺根山地区蛇绿岩稀土元素和Sm-Nd同位素研究.地球化学, 1994,23(4):339~349
毕力赫金矿.内蒙古自治区苏尼特右旗毕力赫金矿勘探地质报告,1993.
曹生儒.对内蒙古古板块构造轮廓的新认识.中国区域地质, 1993,(3):211~215
常印佛,刘湘培,吴言昌.长江中下游铜铁乘矿带.北京:地质出版社,1991
陈昌勇.华北地块北缘金矿床类型及成矿系列.辽宁地质,1998,(3):214~223.
陈骏,王鹤年主编,地球化学,北京:科学出版社,2004.
陈崎,仇甘霖,杜玉申,等.白乃庙—温都尔庙区域构造及华北北缘古板块构造演化.长春地质学院学报,1992,(22):119~129.
方曙,鞠文信,张亚盾.内蒙古东南部中生代构造应力场的多次转换及动力机制探讨.地质力学学报, 2002,8(1):26~35.
高计元,王一先,裘愉卓,等.内蒙古中西部多岛海构造演化.大地构造与成矿学, 2001,25(4):397~404.
高晓峰,郭峰,范蔚茗,等.南兴安岭晚中生代中酸性火山岩的岩石成因.岩石学报, 2005,21:737~748.
葛良胜,卿敏,侯增谦,等,内蒙古毕力赫大型金矿勘查突破过程及启示意义,矿床地质,2009,28(4):390~402.
葛良胜,卿敏,袁士松,等,危机矿山接替资源勘查的理论、技术与思路—以内蒙古毕力赫金矿勘查突破为例,矿物学报,2007,27(增):503~505.
葛良胜,卿敏,张文钊,等,华北板块北缘首例大型高品位隐伏斑岩型金矿床——内蒙古毕力赫金矿,中国地质,2009,(10):1110~1122.
葛良胜,王文成,李汉光,等.滇西北富碱岩体与金矿成矿.北京:地震出版社. 2005.
葛良胜,邹依林,李振华,等.云南马厂箐(铜、钼)金矿床地质特征及成因研究.地质与勘探,2002,38(5):11~17.
葛良胜.滇西北富碱岩浆活动与金多金属成矿系统(博士学位论文).北京:中国地质大学(北京),2007.
葛良胜,张文钊,袁士松,等,蒙古南戈壁-中国东乌旗跨国境成矿带东段金多金属矿床成矿与找矿,北京:地质出版社. 2009.
郭峰,范蔚茗,王岳军,等.大兴安岭南段晚中生代双峰式火山作用.岩石学报, 2001,17: 161~168.
郭胜哲.1986.中朝板块与西伯利亚板块拼合时限的确定及其生物地层学依据[J].沈阳地质矿产研究所所刊,( 14 ) :127~136
何国琦,李茂松.兴蒙-北疆及邻区古生代蛇绿岩的对比研究及其大地构造意义,见:张旗主编.蛇绿岩与地球动力学研究.北京:地质出版社, 1995,104~107.
和钟铧,梁一鸿.内蒙古白乃庙金矿断裂构造控矿研究.地质与勘探,2001,37(2):28~32.
洪大卫,黄怀曾,肖宜君,等.内蒙古中部二叠纪碱性花岗岩及其地球动力学意义.地质学报, 1994,68:219~230.
洪大卫,王式光,谢锡林,等.兴蒙造山带正ε(Nd,t)值花岗岩的成因和大陆地壳生长.地学前缘, 2000,7(2):441~455.
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.矿床地质,2003,22(1):1~12.
侯增谦,潘小菲,杨志明,等.初论大陆环境斑岩铜矿.现代地质,2007,21(2):332~351.
侯增谦.斑岩Cu-Mo-Au矿床:新认识与新进展.地学前缘,2004, 11(1):131~144.
胡家富,张中杰,张慧,等.中国内蒙古高原及周边地带岩石圈三维速度结构.地球物理学进展, 1996,11(4):20~33.
胡朋,聂凤军,江思宏,等.南蒙古典型金属矿床地质特征及结中国相邻地区的找矿启示.矿床地质, 2006.25(增):123~126.
胡骁,许传诗,牛树银.华北地台北缘早古生代大陆边缘演化.北京:北京大学出版社, 1990.6~24.
黄汲清,任纪舜,姜春发,等.中国大地构造及其演化.北京:科学出版社.1980.
贾和义,宝音乌力吉,张玉清.内蒙古达茂旗乌德缝合带特征及大地构造意义同.成矿理工大学学报(自然科学版), 2003.30(1):30~34.
蒋少涌,杨竟红.金属矿床Re-Os同位素示踪与定年研究.南京大学学报(自科版). 2000.
睢程晨.内蒙古自治区毕力赫金矿蚀变和流体包裹体特征分析(硕士学位论文).北京:中国地质大学(北京),2009.
冷福荣,刘旺盛,苏英.1996.华北地台北缘海西期花岗岩类地球化学特征及构造环境探讨[J].内蒙古地质,18-25
李继宏,张万昌.2005.内蒙古东乌旗草原覆盖区遥感构造信息提取[J].地质找矿论丛,20(2):137-142
李述靖,张维杰,耿明山等.1998.蒙古弧地质构造特征及形成演化概论[M].北京:地质出版社
李双庆.1997.内蒙古中部早古生代地体的拼合与增置[J].内蒙古地质,84(1):18-23
李思田,杨世恭. 1987.中国东北部中生代裂陷作用和东北亚断陷盆地[J].中国科学(B辑), 21: 185~195.
李晓勇,郭锋,王岳军.2002.造山后构造岩浆作用研究评述[J].高校地质学报,8(1):68-77
里特曼著,金秉慧译,1979,火成岩的稳定组合计算方法,地质出版社
李颖,刘连登.斑岩型金矿的概念及相关问题讨论.世界地质,1999,18(1):16-22.
梁华英. 2002.玉龙斑岩铜矿带的锆石SHRMP年龄[C].中国基础研究项目报告.
梁日暄.1994.内蒙古中段蛇绿岩特征及地质意义[J].中国区域地质,(1):37-45
梁一鸿,张宏颖.2000.内蒙古中部含金建造的形成环境[J].黄金,21(12):5-9
刘红涛,张旗,刘建明,等. 2004.埃达克岩与Cu-Au成矿作用有待深入研究的岩浆成矿关系[J].岩石学报,20(2): 205~218.
刘益康,徐叶兵.2003.蒙古OyuTolgoi斑岩铜金矿的勘查[J].地质与勘探,39(1):1-4
刘玉强.1994.内蒙古东部晚中生代断陷煤盆地与伸展构造[J].矿床地质,13(3):212-220
刘正宏,刘雅琴,冯本智.2004.华北板块北缘中元古代造山带的确立及其构造演化[J].长春科技大学学报,30(2):110-114
卢造勋,夏怀宽.1992.内蒙古东乌珠穆沁旗-辽宁东沟地学断面[J].地球物理学报,35 (6):765-772
罗飞,罗照华,李述靖等.1995.内蒙古中部白至纪碱性花岗岩的发现及意义[J].现代地质,9(2):203-212
罗飞.1995.内蒙古中部白至纪碱性花岗岩的发现及意义[J].现代地质,9(2):203-211
孟庆任,胡健民,袁选俊,靳久强. 2002.中蒙边界地区晚中生代伸展盆地的结构、演化和成因[J].地质通报, 21:224~231.
内蒙古自治区地质矿产局.1991.内蒙古自治区区域地质志[M].北京:地质出版社
内蒙古自治区地质矿产局.1996.内蒙古自治区岩石地层[M].武汉:中国地质大学出版社
内蒙古自治区第四地质矿产勘查开发院.内蒙古自治区苏尼特右旗毕力赫金矿增储(详查)地质报告,1998
聂凤军,江思宏,张义等.2004.中蒙边境及邻区斑岩型铜矿床地质特征及成因[J].矿床地质,23(2):176-190
聂凤军,江思宏,张义等.2007.中蒙边境中东段金属矿床成矿规律和找矿方向[M].北京:地质出版社
聂凤军,江思宏,赵省民,2000.斑岩型铜金矿床研究新进展[J].内蒙古地质,2(总第95期):1-11
聂凤军,裴荣富,吴良士等.1993.内蒙古白乃庙地区岩浆活动与金属成矿作用[M].北京:北京科学技术出版社
聂凤军,张义,江思宏.2003.中蒙边境中东段我国一侧(北山和二连_东乌旗地区)铜金银矿床成矿规律与找矿方向[A].中国地质调查局地质调查项目技术报告(内部资料)[R],1-14
钱青. 2001. adakite的地球化学特征及成因[J].岩石矿物学杂志,20(3):297~306.
邱家骧,1991,应用岩浆岩岩石学,湖北.武汉,中国地质大学出版社.
邱家骧,1983,火山岩的成分与板块构造环境,地质科技情报,第1期,6-16.
芮宗瑶,黄崇轲,齐国明,等. 1984.中国斑岩型铜(钼)矿[M].北京:地质出版社.
尚恒胜,陶继雄,宝音乌力吉等.2003.内蒙古白云鄂博地区早古生代弧-盆体系及其构造意义[J].地质调查与研究,26(3):160-168
邵积东.1998.内蒙古大地构造分区及其特征[J].内蒙古地质,(2):1-23
邵济安,韩庆军.2000.内蒙古东部早中生代壳慢过渡带—捕虏体岩石高温高压下弹性波速度实验证据[J].中国科学(D辑),30(增):154-160
邵济安,洪大卫,张履桥.2002.内蒙古火成岩Sr-Nd同位素特征及成因[J].地质通报,21(12):817-822
邵济安,刘福田,陈辉等.2001.大兴安岭-燕山中生代岩浆活动与俯冲作用关系[J].地质学报,75(4):56-63
邵济安,唐克东.1995.蛇绿岩与南蒙古洋的演化,见张旗主编,蛇绿岩与地球动力学研究[M].北京:地质出版社,117-120
邵济安,张履桥,牟保磊.1999.大兴安岭中生代伸展造山过程中的岩浆作用[J].地学前缘,6(4):339-346
邵济安.1991.中朝板块北缘中段地壳演化,北京:北京大学出版社,11-91
沈存利,苏宏伟,王守光.2004.内蒙古铜矿床区域成矿特征初步研究[J].西北地质,37(3):43-50
唐克东,张允平.1991.内蒙古缝合带的构造演化,见:肖序常,汤粗庆主编古中亚夏合巨型缝合带南缘构造演化[M].北京:北京科学技术出版社,30-54
唐克东.1989.中朝陆台北侧褶皱带构造发展的几个问题[J].现代地质,3(2):195-204,
唐克东.1992.中朝板块北侧褶皱带构造演化及成矿规律[M].北京:北京大学出版社,60-179,223-242
唐纳.W.海因德曼著,邱家骧,王人镜,马昌前译,火成岩与变质岩岩石学,湖北武汉:中国地质大学出版社,1989.
陶继雄,胡凤翔,陈志勇.2003.华北陆块北缘印支期S型花岗岩带特征及其构造环境[J].岩石矿物学杂志,22(2):112-118
滕吉文.2007.地壳内部金属矿产聚集的深层动力过程与兴、蒙成矿域找矿探查的战略意义[A],全国深部找矿工作会议[C],安徽合肥,9,26-29
涂光炽. 1989.关于富碱侵入岩[J].矿产与地质,13(3):1.
涂光炽等.2000.中国超大型矿床[M].北京:科学出版社,397-425
王荃.1986.内蒙古中部中朝与西伯利亚古板块间缝合线的确定[J].地质学报,1:31-43
王瑞廷,欧阳建平,蒋敬业.1999.内蒙古东部半干旱草原残丘景观区铜多金属元素表生地球化学异常特征及其评价指标体系的构建[J].矿产与地质,13(6):348-13
王瑜.1994.中国东部内蒙燕山地区晚古生代晚期-中生代的造山作用过程[D].北京:中国地质科学研究院
王瑜.1996.晚古生代末-中生代内蒙古燕山地区造山过程中的岩浆热事件与构造演化[J].现代地质,10(1):66-75
王玉净,樊志勇.1997.内蒙古西拉木伦河北部蛇绿岩带中二叠纪放射虫的发现及其地质意义[J].古生物学报,36(1):58-69
王喻.1996.中国东部内蒙古造山带晚古生代晚期-中生代的造山作用过程[M].北京:地质出版社
王喻.1998.中生代以来华北地区造山带与盆地的演化及动力学[M].北京:地质出版社
王元龙,张旗,王强,等. 2003.埃达克质岩与Cu-Au成矿作用关系的初步探讨[J].岩石学报,19:543~550.
王肇芬,赵俊磊,王璞译.1990.世界斑岩铜矿.北京:地质出版社.
吴泰然,张臣,万基虎.1998.内蒙古温都尔庙地区温都尔庙群的形成环境和构造意义[J].高校地质学报,4(2):168-176
武警黄金地质研究所.内蒙古自治区苏尼特右旗毕力赫金矿区Ⅱ矿带15-40线详查报告,2008.8
肖成东,付国立,赵利青.2000.内蒙古锡盟—赤峰北部板块构造演化与金矿床[J].黄金地质,6(2):17-20
肖荣阁,隋德才,罗照华等.1995内蒙古北部早元古代变质岩系的发现及其岩石学研究[J].现代地质,9(2):142-148
徐备,J,Charvet,张福勤.2001.内蒙古北部苏尼特左旗蓝片岩岩石学和年代学研究[J].地质科学,36(4):424-434
徐备,陈斌,张巨等.1994.华北板块北缘中段含铁变质岩系的时代和构造环境初探[J].地质论评, 40(4):307-311
徐备,陈斌.1997.内蒙古北部华北板块与西伯利亚板块之间中古生代造山带的结构及演化[J].中国科学(D辑),27(3):227-232
徐备.1998.内蒙古北部温都尔庙群北带沉积环境及构造意义[J].,Scientia geologica sinica,33(4):406-411
徐备.1998.内蒙古北部温都尔庙群北带沉积环境及构造意义[J].地质科学,33(4):406-411
徐备.2001.内蒙古北部苏尼特左旗蓝片岩岩石学和年代学研究[J].地质科学,36(4):424-434
许立权,邓晋福,陈志勇.2004.内蒙古中部印支期强过铝质花岗岩的相平衡约束及动力学背景[J].地质通报,23(8):790-794
许立权,邓晋福,陈志勇.2004.内蒙古中部印支期强过铝质花岗岩的相平衡约束及动力学背景[J].地质通报,23(8):790-794
许立权,贾和义,张玉清等.2004.白云鄂博地区碱性正长岩特征及其意义[J].地质调查与研究,27(1):43-47
许立权.2004.内蒙古中部印支期强过铝质花岗岩的相平衡约束及动力学背景[J].地质通报,23(8):790-794
薛重生.1997.遥感技术在区域地质调查中的应用研究进展[J].地质科技情报,16(增):16-22
杨志明,侯增谦,李振清,宋玉财,谢玉玲. 2008.西藏驱龙斑岩铜钼矿床中UST石英的发现:初始岩浆流体的直接记录[J].矿床地质, 27: 188~199.
冶金工业部地质研究所.1984.中国斑岩铜矿.北京:科学出版社.
翟安民,李增慧,汪玉麟等.1981.内蒙古包日汗区温都尔庙群变质岩系的构造演化特点[J].中国地质科学院院报,3(1):21-31
翟裕生,林新多. 1993.矿田构造学.北京:地质出版社
翟裕生,邓军,王建平等,深部找矿问题研究,矿床地质,2004,23(2):142-149
翟裕生,彭润民,向运川,等.2004.区域成矿研究法[M].北京:中国大地出版社.
翟裕生.论成矿系统.地学前缘,1999,1.
张旗,王焰,刘伟,等. 2002.埃达克岩的特征及其意义[J].地质通报,21:431~435.
张旗,许继峰,王焰,等. 2004.埃达克岩的多样性[J].地质通报,23(9-10):959~965.
张臣,吴泰然.1998.内蒙古温都尔庙群变质基性火山岩Sm-Nd、Rb-Sr同位素年代研究[J].地质科学,33(1):25-30
张臣,吴泰然.1999.内蒙古苏左旗南部早古生代蛇绿混杂岩特征及其构造意义[J].地质科学,34(3):381-389
张臣,吴泰然.1999.内蒙古苏左旗南部早古生代蛇绿混杂岩特征及其构造意义[J].地质科学,34(3):381—389
张臣,吴泰然.2001.内蒙古苏左旗南部华北板块北缘中新元古代-古生代裂解-汇聚事件的地质记录[J].岩石学报,17(2):199-205
张臣.1999.内蒙古苏左旗南部温都尔庙群地层研究的新进展[J].地学前缘,6(3):112
张义,聂凤军,江思宏.2003.中蒙边境欧玉陶勒盖大型铜-金矿床的发现及对找矿勘查工作的启示[J].地质通报,22(9):708-712
张义,聂凤军,孙彬彬等.2005.内蒙古中东部浅覆盖区化探岩屑测量方法研究及靶区优选应用[J].中国地质,32(4):696-705
张振法,葛昌宝.2000.内蒙古东部区深部构造特征和大地构造问题浅议[J].内蒙古地质,(3):6-13
张振法.1990.显生宙蒙古洋地球动力学环境及有关问题探讨[J].地质科技情报,3
张振法.1993.西伯利亚板块和中朝板块间古地球动力学环境及两大板块中段缝合位置[J].地质科技情报,1
张振法.1994.根据深部地球物理资料和古板块构造格架重新厘定槽台界线[J].内蒙古地质,1-15
中国北方板块构造论文集编委会.1986.中国北方板块构造论文集(第一集) [C].北京:地质出版社
中国北方板块构造论文集编委会.1987.中国北方板块构造论文集(第二集) [C].北京:地质出版社
中国科学院矿床地球化学开放研究实验室,矿床地球化学[M].北京:地质出版社,1997
朱英等.2004.中国及邻区大地构造和深部构造纲要[M].北京:地质出版社
朱永锋,孙世华,毛骞,赵光. 2004.内蒙古锡林格勒杂岩的地球化学研究:从Rodinia聚合
到古亚洲洋闭合后碰撞造山的历史记录[J].高校地质学报, 10: 343~355.
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |