西准噶尔宏远斑岩型钼(铜)矿地质特征及成因
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摘要
宏远钼(铜)矿床产于新疆西准噶尔达尔布特南构造岩浆岩带的宏远斑岩体中。斑岩体岩性为灰色花岗闪长斑岩、灰白色二长花岗斑岩。侵位于石炭系及晚石炭世加甫沙尔苏岩体中。达尔布特南构造岩浆岩带是中亚成矿带的重要组成部分,大地构造位于唐巴勒—卡拉麦里古生代复合沟弧带与准噶尔中央地块结合部位,侵入岩发育,构造活动强烈,成矿条件优越。近年来,此带分别发现了吐克吐克铜(金)矿床、宏远钼(铜)矿床和红山铜矿点。目前,包括前人发现和评价的包古图斑岩金(铜)矿床在内,在达尔布特断裂带南东盘的多数岩体中均已有斑岩铜—钼—金矿(化)的发现,初步显现出本区是一个斑岩型铜—钼—金矿集区。
论文在前人区域地质调查与研究成果的基础上,以成矿系统理论为指导,运用岩石学、构造地质学、矿床学、放射性同位素测年和示踪,主量元素、微量元素和稀土元素等多学科的方法进行了研究。
宏远斑岩体为准铝质—过铝质A型花岗岩。于斑岩中新获得LA-ICP-MS锆石U-Pb年龄为302.20±3.1Ma和300.80±3.6M(与前人获得的301Ma的锆石U-Pb年龄十分接近);获得辉钼矿化带的辉钼矿Re-Os等时线年龄为294.6±4.6Ma。成岩和成矿时代基本一致。斑岩体控矿裂隙发育较发育,控制着矿体的规模、形态、品位变化和产状。以矿体为中心,向两侧蚀变分带规律较清楚。由内向外依次为石英—绢云母化带、青磐岩化带,由内向外蚀变强度、矿化逐渐变弱。
岩体具面状褐铁矿、孔雀石、辉钼矿化,岩体中发育密集的节理和裂隙,铜(钼)矿体厚度较大,矿化类型为细脉状、团斑状和浸染状;与成矿有关的围岩蚀变主要为钾化、绿泥石化、绢云母化、绿帘石化,总体特征表明宏远铜(钼)矿为典型斑岩型矿床。斑岩体值低(Sr)i。Sr-Nd同位素组成表明成岩及成矿中有地幔物质的混染。
宏远钼(铜)矿不同于该成矿带上较早发现的包古图埃达克质斑岩(铜)金矿,这为该区寻找新的斑岩型矿床类型提供了新信息。
The Hongyuan porphyry Mo (Cu) deposit, discovered in2010, is located in the WestJunggar region of Xinjiang of northwest China. The rock type of the Hongyuan plutonincludes granodiorite and Monzogranite. The deposit is hosted within the Karamaygranodiorite porphyry that intruded into Early Carboniferous sedimentary strata andJiafusaersu pluton. The southern Darbut teoctonic magmatic metallogenic belts is theimportant part of the huge Central Asia metallogenic domain. The belt is located in thecollage zone between Tangbale composite trench-arc belt and Junggar central block andhas the predominant metallogenic capacity because of the extensive magmatim and strongtectonic activity. Recent years, preliminary studies in terms of field geological mapping,mineral resources surveys, structural geology, and petrography, geochemistry andgeochronology of several key plutonic bodies in west Junggar have allowed us to findsome new ore occurrences including Tuketuke porphyry copper(molybdenum) deposit,Hongyuan porphyry molybdenum (copper) deposit and Hongshan porphyrycopper(molybdenum) deposit reported in this paper, and to characterize these porphyrydeposits. Consenquently, the southern Darbut teoctonic magmatic metallogenic belts canbe presented in west Junggar based on the spatial and temporal distribution and therock-type of ore-bearing intrusive bodies for these ore occurrences associated with theBaogutu copper-gold deposit in the Western segment of the belt.
Combing the previous study results, this paper researches the deposit using petrology,structural geology, mineral deposit geology, radioisotope dating and tracing, major andtrace elements in terms of the metallogenic system theory.
LA-ICPMS U-Pb method was used to date the zircons from the peraluminous A-typegranodiorite samples of the porphyry. Analyses of12spots of zircons from thegranodiorite samples yield a U-Pb weighted mean age of302.20±3.1Ma300.80±3.6M (2).Re-Os dating for five molybdenite samples obtained from two prospecting trenches andthree outcrops in the deposit yield a Re-Os isochron age of294.6±4.6Ma (2). TheRe-Os isochron age of the molybdenite is consistent with the U-Pb age of the granodioriteporphyry.
The joint and fissure of the porphyry control the scale, morphology, grade andoccurrences of the orebodies. The Quartz-sericite zone, propylitic alteration zone from thecenter to rim of the porphyry suggested the alteration intensity increase from the center tothe outer. The pluton suffered from the alteration of planar limonite, intensive development of malachite, molybdenite mineralization and rock joints and fractures are observed in thepluton everywhere. The thickness Cu (Mo) mineralization type is fine veined, Leagueporphyritic and disseminated; the alteration of wall rock related to mineralization aremainly potassic, chlorite, sericite, epidote petrochemical. These general characteristicsindicate that the Hongyuan Mo (Cu) deposit is typical porphyry deposit. Low initial Sr (Sri)and Sr-Nd isotopic composition of the porphyry demonstrated the contamination of themantle material in the magmatism and mineralization.
The Hongyuan Mo (Cu) deposit are different from the Baogutu Au(Cu) depositrelated to the adakitic porphyry which are discovered early in this belt. The results providea new significance information for the exploration of new porphyry deposits.
论文在前人区域地质调查与研究成果的基础上,以成矿系统理论为指导,运用岩石学、构造地质学、矿床学、放射性同位素测年和示踪,主量元素、微量元素和稀土元素等多学科的方法进行了研究。
宏远斑岩体为准铝质—过铝质A型花岗岩。于斑岩中新获得LA-ICP-MS锆石U-Pb年龄为302.20±3.1Ma和300.80±3.6M(与前人获得的301Ma的锆石U-Pb年龄十分接近);获得辉钼矿化带的辉钼矿Re-Os等时线年龄为294.6±4.6Ma。成岩和成矿时代基本一致。斑岩体控矿裂隙发育较发育,控制着矿体的规模、形态、品位变化和产状。以矿体为中心,向两侧蚀变分带规律较清楚。由内向外依次为石英—绢云母化带、青磐岩化带,由内向外蚀变强度、矿化逐渐变弱。
岩体具面状褐铁矿、孔雀石、辉钼矿化,岩体中发育密集的节理和裂隙,铜(钼)矿体厚度较大,矿化类型为细脉状、团斑状和浸染状;与成矿有关的围岩蚀变主要为钾化、绿泥石化、绢云母化、绿帘石化,总体特征表明宏远铜(钼)矿为典型斑岩型矿床。斑岩体值低(Sr)i。Sr-Nd同位素组成表明成岩及成矿中有地幔物质的混染。
宏远钼(铜)矿不同于该成矿带上较早发现的包古图埃达克质斑岩(铜)金矿,这为该区寻找新的斑岩型矿床类型提供了新信息。
The Hongyuan porphyry Mo (Cu) deposit, discovered in2010, is located in the WestJunggar region of Xinjiang of northwest China. The rock type of the Hongyuan plutonincludes granodiorite and Monzogranite. The deposit is hosted within the Karamaygranodiorite porphyry that intruded into Early Carboniferous sedimentary strata andJiafusaersu pluton. The southern Darbut teoctonic magmatic metallogenic belts is theimportant part of the huge Central Asia metallogenic domain. The belt is located in thecollage zone between Tangbale composite trench-arc belt and Junggar central block andhas the predominant metallogenic capacity because of the extensive magmatim and strongtectonic activity. Recent years, preliminary studies in terms of field geological mapping,mineral resources surveys, structural geology, and petrography, geochemistry andgeochronology of several key plutonic bodies in west Junggar have allowed us to findsome new ore occurrences including Tuketuke porphyry copper(molybdenum) deposit,Hongyuan porphyry molybdenum (copper) deposit and Hongshan porphyrycopper(molybdenum) deposit reported in this paper, and to characterize these porphyrydeposits. Consenquently, the southern Darbut teoctonic magmatic metallogenic belts canbe presented in west Junggar based on the spatial and temporal distribution and therock-type of ore-bearing intrusive bodies for these ore occurrences associated with theBaogutu copper-gold deposit in the Western segment of the belt.
Combing the previous study results, this paper researches the deposit using petrology,structural geology, mineral deposit geology, radioisotope dating and tracing, major andtrace elements in terms of the metallogenic system theory.
LA-ICPMS U-Pb method was used to date the zircons from the peraluminous A-typegranodiorite samples of the porphyry. Analyses of12spots of zircons from thegranodiorite samples yield a U-Pb weighted mean age of302.20±3.1Ma300.80±3.6M (2).Re-Os dating for five molybdenite samples obtained from two prospecting trenches andthree outcrops in the deposit yield a Re-Os isochron age of294.6±4.6Ma (2). TheRe-Os isochron age of the molybdenite is consistent with the U-Pb age of the granodioriteporphyry.
The joint and fissure of the porphyry control the scale, morphology, grade andoccurrences of the orebodies. The Quartz-sericite zone, propylitic alteration zone from thecenter to rim of the porphyry suggested the alteration intensity increase from the center tothe outer. The pluton suffered from the alteration of planar limonite, intensive development of malachite, molybdenite mineralization and rock joints and fractures are observed in thepluton everywhere. The thickness Cu (Mo) mineralization type is fine veined, Leagueporphyritic and disseminated; the alteration of wall rock related to mineralization aremainly potassic, chlorite, sericite, epidote petrochemical. These general characteristicsindicate that the Hongyuan Mo (Cu) deposit is typical porphyry deposit. Low initial Sr (Sri)and Sr-Nd isotopic composition of the porphyry demonstrated the contamination of themantle material in the magmatism and mineralization.
The Hongyuan Mo (Cu) deposit are different from the Baogutu Au(Cu) depositrelated to the adakitic porphyry which are discovered early in this belt. The results providea new significance information for the exploration of new porphyry deposits.
引文
Andersen T. Correction of common lead in U–Pb analyses that do not report204Pb[J]. Chemical Geology,2002,192:59-79.
Ballard J R,Palin J M and Williams I S. Two ages of porphyry intrusion resolved for the super-giantChuquicamata copper deposit of northern Chile by LA–ICP–MS and SHRIMP[J]. Geology,2001,9:383-386.
Barbarin B. A review of the relationships between granitoid type,their origins and their geodynamicenvironments[J]. Lithos,1999,46:605-626.
Bonin B. A-type granites and related rocks: Evolution of a concept,problems and prospects[J]. Lithos,2007,97:1-29.
Chappell B W and White A J R Wang,J B. Two Contrasting granite types[J]. Pac Geol,1974,8:173-174.
Chen Bo and Arakawa Y. Elemental and Nd-Sr isotopic geochemistry of granitoids from the West Junggarfoldbelt (NW China),with implications for Phanerozoic continental growth[J]. Geochimica etCosmochimica Acta.2005,69(5):1307-1320.
Chen Bo,Jahn B M. Genesis of post-collisional granitoids and basement nature of the Junggar Terrane,NWChina: Nd-Sr isotope and trace element evidence[J]. J Asian Earth Sci,2004,23(5):691-703.
Collins W J,Beams S D,White A R and Chappell B W. Nature and origin of A-type granites with particularreference to southeastern Australia[J]. Contrib Mineral Petrol,1982,80:189-200.
Compston W,Williams I S,Kirschvink J L et a1. Zircon U-Pb ages for the Early Cambrian time-scale[J].Joumal of GeologicalSociety,1992,149:171-184.
Creaser R A,Price R C and Wormald R J. A-type granites revisited:Assessment of a residual-sourcemodel[J]. Geology,1991,19:163-166.
Defant MJ and Drummond MS. Derivation of some modern arc magmas by melting of young subductedlithosphere[J]. Nature,1990,34:662-665.
Defant MJ and Kepezhinskas P. Evidence suggests slab melting in arc magmas[J]. EOS,2001,82(6):67-69.
Eby G N. Chemical subdivision of the A-type granitoids:Petrogenetic and tectonic implications[J].Geology,1992,20:641-644.
Eby G N. The A-type granitoids:A review of their occurrence and chemical characteristics and speculationson their petrogenesis[J]. Lithos,1990,26:115-134.
Feng Yi-ming M,Coleman,R G,Tilton,G R. Tectonic evolution of the West Junggar region,Xinjiang,China[J]. Tectonics,1989,8:729-752.
Frost C D and Frost B R. Reduced rapakivi-type granites: The tholeiite connection[J]. Geology,1997,25:647-650.
Frost C D,Frost B R,Chamberlain K R,et a1. Petrogenesis of the143Ga Sherman batholith,SE Wyoming,USA: A reduced,rapakivi-type anorogenic granite[J]. J Petrol,1999,40:1771-1802.
Geng HY,Sun M,Yuan C,Xiao WJ,et a1. Geochemical,Sr–Nd and zircon U–Pb–Hf isotopic studies ofLate Carboniferous magmatism in the West Junggar,Xinjiang: Implications for ridge subduction?[J].Chemical Geology,2009,266(3-4):364-389.
Gaoxue Yang,Yongjun Li,M. Santosh,et al. Geochronology and geochemistry of basaltic rocks from theSartuohai ophiolitic mélange,NW China: Implications for a Devonian mantle plume within theJunggar Ocean. Journal of Asian Earth Sciences[J]. Journal of Asian Earth Sciences,2012,59:141-155.
Han Baofu,Wang S G,Jahn B M,et a1. Depleted-mantle source for the Ulungur River A-type granites fromNorth Xinjiang,China:Geochemistry and Nd-Sr isotopic evidence. and implications for Phanerozoiccrustal growth[J]. Chemical Geology,1997,138:135-159.
Harris C. The petrology of lavas and associated plutonic inclusions of Ascension Island[J]. J Petrol,1983,24:424-470.
King P L,Chappell B W and White A J R Are. A-type granites the high-temperature felsic grenites Evidencefrom fractionated granites of the Wangrah Suite[J]. Aust J Earth Sci,2001,48:501-514.
King P L,White A J R and Chappell B W. Characterization and origin of A-type granites of the LachlanFold Belt,southeastern Australia[J]. J Petrol,1997,36:371-391.
Kwon S T,Tilton G R,Coleman R G,et a1. Isotopic studies bearing on the tectonics of the West Junggarregion,Xinjiang,China[J]. Tectonics,1989,8(4):719-727.
Liu Xioa-ming,Gao S,Yuan HL,et a1. Analysis of42major and trace elements in glass standard referencematerials by193nm LA-ICP-MS[J]. Acta Petrologica Sinica,2002,18(3):408–418.
Liu YL,Guo LS,Liu YD,et a1. Geochronology of Baogutu porphyry copper deposit in Western Junggararea,Xinjiang of China[J]. Science in China Series D: Earth Sciences,2009,52(10):1543-1549.
Loiselle M C and Wones D R. Characteristics and origin of anorogenic granites[J]. Geol Soc Am Bull,1979,11:468.
Ludwig K R. Isoplot-A plotting and regression program for radiogenic-isotope data[R]. US GeologicalSurvey Open-File Report,1991,39:91-445.
Maniar P D and Picooli P M. Tectonic discrimination of granitoids[J]. Geol Soc Am Bull,1989,101:635-643.
Pearce J A,Harris N B W and Tindle A G. Trace element discrimination diagrams for tectonic interpretationof granitic rock[J]. J Petrol,1984,25:956-983.
Pidgeon R T,Nemchin A A,Hitchen G J. Internal structures of zircons from Archaean granites from heDarling Range batholith:implications for zircon stability and the interpretation of zircon U-Pb ages[J].Contributions to Mineralogy and Petrology,1998,132:288-299.
Rogers J J W and Greenberg J E. Late-orogenic,post-orogenic,and anorogenic granites: Distinction bymajor-element and trace-element chemistry and possible origins[J]. J Geol,1990,98:291-310.
Seltmann R and Porter TM. The Porphyry Cu-Au/Mo Deposits of Central Eurasia:1. Tectonic,Geologic&Metallogenic Setting and Significant Deposits[J].(in)Porter T M(eds) Super Porphyry Copper&Gold Deposits-A Global Perspective,PGC Publishing,2005,2:467-511.
Shen,P,Shen,Y C,Liu,T B,et al. Geochemical signature of porphyries in the Baogutu porphyry copperbelt,western Junggar,NW China[J]. Gondwana Research,2009,16:227-242.
Shen,P,Shen,Y C,Wang,J B,et al. Methane-rich fluid evolution of the Baogutu porphyry Cu–Mo–Audeposit,Xinjiang,NW China[J]. Chemical Geology,2010,275:78-98.
Shen,P,Shen,Y,Li,X H. Northwest Junggar,Xiemisitai Mountains,China: A geochemical andgeochronological approach[J]. Lithos,2012,141:103-118.
Sillitoe RH. Characteristics and controls of the largest porphyry copper‐gold and epithermal gold depositsin the circum‐Pacific region[J]. Australian Journal of Earth Sciences,1997,44(3):373-388.
Sillitoe Richard H. A Plate Tectonic Model for the Origin of Porphyry Copper Deposits[J]. EconomicGeology,1972,67(2):184-197.
Sillitoe Richard H and Mortensen James K. Longevity of porphyry copper formation at quellaveco,Peru[J].Economic Geology,2010,105(6):1157-1162.
Staudigel H,Davies G R,Hart S R,et a1. Large scale isotopic Sr,Nd and O isotopic anatomy of alteredoceanic crust: DSDP/ODP sites417/418[J]. Earth Planet SciLett,1995,130(1/4):169-185.
Sun SS and McDonough WF. Chemical and isotopic systematics of oceanic basalts: implications for mantlecomposition and process s. In: Sauders AD and Norry MJ(eds). Magmatism in the OceanBasins[J].Geological Society. Special Publication,1989,42:3l3-345.
Tang GJ,Wang Q,Wyman DA,et a1. Ridge subduction and crustal growth in the Central Asian OrogenicBelt: Evidence from Late Carboniferous adakites and high-Mg diorites in the western Junggar region,northern Xinjiang (west China)[J]. Chemical Geology,2010,277(3-4):281-300.
Turner S P,Foden J D and Morrison R S. Derivation of some A-type magmas by fractionation of basalticmagama: an example from the Padthaway Ridge,South Australia[J].Lithos,1992,28:151-179.
Wang Q,Zhao Z H,Xu J F,et al. Carboniferous adakite-high-Mg andesite-Nb-enriched basaltic rock suitesin the Northern Tianshan area:Implications for Phanerozoic crustal growth in the Central Asia OrogenicBelt and Cu-Au mineralization[J]. Acta Petrologica Sinica,2006,22(1):11-30.
Whalen J B,Currie K and Chappell. B W. A-type granites:geochemical characteristics,dirimination andpetrogenesis[J]. Contrib,Minera1,Petro1,1987,95:407-419.
Xiao,W J,Han,C M Yuan,C,et al. Middle Cambrian to Permian subduction-related accretionaryorogenesis of North Xinjiang,NW China: implications for the tectonic evolution of Central Asia[J].Journal of Asian Earth Sciences,2008,32:102-117.
Xiao,WJ,Huang,BC,Han,CM,et al. A review of the western part of the Altaids: A key to understandingthe architecture of accretionary orogens[J]. Gondwana Research,2010,18:253-273.
Xiao,W J,Kusky,T M. Geodynamic processes and metallogenesis of the Central Asian and relatedorogenic belts: introduction[J]. Gondwana Research,2009,16:167-169.
Xiao,W J,Windley,B F,Badarch,G,et al. Palaeozoic accretionary and convergent tectonics of thesouthern Altaids: implications for the lateral growth of Central Asia[J]. Journal of the GeologicalSociety,London,2004,161:339-342.
Xiao,W J,Windley,B F,Yuan,C,et al. Paleozoic multiple subduction-accretion processes of the southernaltaids[J]. American Journal of Science,2009,309:221-270.
Yang J H,Wu F Y,Chung S L,et al. A hybrid origin for the Qianshan A-type granite,northeast China:Geochemical and Sr-Nd-Hf isotopic evidence[J]. Lithos,2006,89:89-106.
Yin JY,Yuan C,Sun M,et al. Late Carboniferous high-Mg dioritic dikes in Western Junggar,NW China:Geochemical features,petrogenesis and tectonic implications[J]. Gondwana Research,2010,17(1):145-152.
P.亨德森主编.稀土元素地球化学[M].北京:地质出版社,1989.20-178.
北京大学地质系编.斑岩铜矿及其找矿[M].北京:冶金工业出版社,1978.159.
成守德,王广瑞,杨树德,等.新疆古板块构造[J].新疆地质,1986,4(2):1-26.
成守德,王元龙.新疆大地构造演化基本特征[J].新疆地质,1998,16(2):97-107.
成守德,王元龙.中亚地壳发展演化与成矿[M].乌鲁木齐:新疆人民出版社,2000.
陈毓川,裴荣富,王登红.三论矿床的成矿系列问题[J],地质学报,2006a,80(10):1501-1508.
陈毓川,王登红,徐志刚,等.对中国成矿体系的初步探讨[J].矿床地质,2006b,25(2):155-163.
董连慧,冯京,李凤鸣.2004年新疆地质矿产勘查进展及2005年工作思路[J].新疆地质,2005,23(1):1-3.
董连慧,冯京,李凤鸣.新疆非油气矿产地质勘查“十五”主要成果及“十一五”地质找矿重点[J].新疆地质,2006c,24(1):1-3.
董连慧,冯京,刘德权等,新疆成矿单元划分方案研究[J].新疆地质,2010a,28(1):1-15.
董连慧,李凤鸣,屈迅.2008年新疆地质矿产勘查主要成果及国土资源部与新疆维吾尔自治区“358项目”工作部署[J].新疆地质,2009a,27(1):1-4.
董连慧,屈迅,朱志新,张良臣.新疆大地构造演化与成矿[J].新疆地质,2010b,28(4):351-357.
董连慧,徐兴旺,屈迅,李光明.初论环准噶尔斑岩铜矿带的地质构造背景与形成机制[J].岩石学报,2009b,25(4):713-737.
杜琦.斑岩铜矿成因探讨[M].北京:地质出版社,2008.91.
冯京,徐仕琪,赵青,等.新疆斑岩型铜矿成矿规律及找矿方向[J].新疆地质.2010,28(1):43-51.
高合明.德兴斑岩铜矿床成矿作用动力学与成矿作用复杂性[M].北京:原子能出版社,1999.89.
高山林,何治亮,周祖翼.西准噶尔克拉玛依花岗岩体地球化学特征及其意义[J].新疆地质,2006,24(2):125–130.
辜平阳,李永军,王晓刚,等.西准噶尔达尔布特SSZ型蛇绿杂岩的地球化学证据及构造意义[J].地质论评,2011,57(1):36-44.
辜平阳,李永军,张兵,等.西准达尔布特蛇绿岩中辉长岩LA-ICP-MS锆石U-Pb测年[J].岩石学报,2009,25(6):1364-1372.
韩宝福,季建清,宋彪,等.新疆准噶尔晚古生代陆壳垂向生长(I):后碰撞深成岩浆活动的时限[J].岩石学报,2006,22(5):1077–1086.
韩宝福,何国琦,王式洸.后碰撞岩浆活动、底垫作用及准噶尔盆地基底的性质[J].中国科学(D辑),1999,29(1):16-21.
韩宝福,何国琦,王式洸,等.新疆北部后碰撞幔源岩浆活动与陆壳纵生长[J].地质论评,1998a,44(4):396-406.
韩宝福,何国琦,吴泰然,等.天山早古生代花岗岩锆石U-Pb定年、岩石地球化学特征及其大地构造意义[J].新疆地质,2004,22(1):4-11.
韩宝福,王式洸,等.新疆乌伦古河碱性花岗岩Nd同位素特征及其对显生宙地壳生长的意义[J].科学通报,1997,42(17):1829-1832.
韩宝福,王式洗,孙元林,等.正εNd(t)值的准铝-过铝花岗岩:新疆也布山岩体[J].科学通报,1998b,43(12):1324-1328.
何国琦,朱永峰.中国新疆及其邻区地质矿产对比研究[J].中国地质,2006,33(3):451-460.
何晓刚,康磊,王晓刚,等.西准噶尔夏尔莆岩体岩浆混合的岩石化学证据[J].新疆地质,2011,29(3):251–256.
贺敬博,陈斌.西准噶尔克拉玛依岩体的成因:年代学、岩石学和地球化学证据[J].地学前缘,2011,18(2):191-211.
洪大卫,王式洸,韩宝福,等.碱性花岗岩的构造环境分类及其鉴别标志[J].中国科学(B辑),1995,25(4):418-426.
洪大卫,王式洸,谢锡林等.兴蒙造山带正εNd(t)值花岗岩的成因和大陆地壳生长[J].地学前缘,2000,7(2):441-455.
洪大卫,王涛,童英.中国花岗岩概述[J].地质论评,2007,53,增刊:9-16.
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):131-144.
侯增谦.大陆碰撞成矿论[J].地质学报,2010,84(1):30-58.
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.
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,2003b,22(1):319-333.
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,2003a,22(1):1-22.
侯增谦,杨志明.中国大陆环境斑岩型矿床:基本地质特征、岩浆热液系统和成矿概念模型[J].地质学报,2009,83(12):1779-1816.
贾小辉,王强,唐功建.A型花岗岩的研究进展及意义[J].大地构造与成矿学,2009,33(3):465-480.
简伟,柳维,石黎红.斑岩型钼矿床研究进展[J].矿床地质,2010,29(2):308-316.
金成伟,张秀棋.新疆西准噶尔花岗岩类的时代及其成因[J].地质科学,1993,28(1):28–36.
康磊.新疆西准噶尔夏尔莆岩浆混合花岗岩体的研究[D].西安:长安大学,2010.
康磊,李永军,张兵,等.新疆西准噶尔夏尔莆岩体岩浆混合的岩相学证据[J].岩石矿物学杂志,2009,28(5):423-432.
李昌年.岩浆混合作用及其研究评述[J].地质科技情报,2002,21(4):49–54.
李华芹,陈富文.中国新疆区域成矿作用年代学[M].北京:地质出版社,2004.11-15,83-217,259-276.
李锦轶,肖序常.对新疆地壳结构与演化几个问题的简单评述[J].地质科学,1999,34(4):405-419.
李卫东,付延龙,李文铅.鲍尔羌吉韧变花岗岩类地质特征[J].新疆地质,2000,18(2):129-135.
李卫东,彭湘萍,康正文等.东昆仑木孜塔格地区畅流沟蛇绿岩岩石地球化学特征及其构造意义[J].新疆地质,2003,21(3):263-268.
李卫东,涂其军,高永峰等.新疆哈密市路白山一带片麻状花岗岩锆石SHRIMP U-Pb定年及其地质意义[J].中国地质,2010,37(5):1273-1283.
李卫东,王晓东,范新丽.东准噶尔鲍尔羌吉一带热隆伸展构造的厘定[J].新疆地质,2002,20(1):29-33.
李卫东,周继兵,李永军等.西天山特克斯达坂岩基解体的地球化学证据及钼找矿意义[J].岩石矿物学杂志,2008,27(5):405-412.
李辛子,韩宝福,季建清,等.新疆克拉玛依中基性岩墙群的地质地球化学和K-Ar年代学[J].地球化学,2004,33(6):574-584.
李永军,王冉,李卫东,等.西准达尔布特南构造岩浆岩带斑岩型铜-钼矿新发现及找矿思路[J].岩石学报,2012,28(7):2009-2014.
李永军,佟丽莉,张兵,等.论西准噶尔石炭系希贝库拉斯组与包古图组的新老关系[J].新疆地质,2010,28(2):130–136.
李辛子,韩宝福,季建清,等.新疆克拉玛依中基性岩墙群的地质地球化学和K-Ar年代学[J].地球化学,2004,33(6):574–584.
李宗怀,韩宝福,李辛子,等.新疆准噶尔地区花岗岩中微粒闪长质包体特征及后碰撞花岗质岩浆起源和演化[J].岩石矿物学杂志,2004,23(3):214–226.
刘宝良. CIPW标准矿物计算法应用时存在问题的探讨[J].地质与资源,2001,10(3):180-189.
刘德权,唐延龄,周汝洪.中国新疆矿床成矿系列[M].北京,地质出版社,1996.11-15,83-217,259-276.
刘德权,唐延龄,周汝洪,等.中国新疆铜矿床和镍矿床[M].北京:地质出版社,2005.11-15,177-245.
马铁球,伍光英,贾宝华,等.南岭中段郴州一带中、晚侏罗世花岗岩浆的混合作用—来自镁铁质微粒包体的证据[J].地质通报,2005,24(1):506–512.
庞振甲,李永军,赵玉梅,等.西准阿克巴斯陶铝质A型花岗岩厘定及意义[J].新疆地质,2010,28(2):119-124(in Chinese with English abstract).
邱检生,王德滋,蟹泽聪史,等.福建沿海铝质A型花岗岩的地球化学及岩石成因[J].地球化学,2000,29(4):313-321.
芮宗瑶.中国斑岩铜(钼)矿床[M].北京:地质出版社,1984.350.
申萍,沈远超.西准噶尔与环巴尔喀什斑岩型铜矿床成矿条件及成矿模式对比研究[J].岩石学报,2010,26(8):2299-2316.
沈远超,金成伟.西准噶尔地区岩浆活动与金矿化作用[M].北京:科学出版社,1993.113-171.
舒良树,卢华复,印栋浩,等.新疆北部古生代大陆增生构造[J].新疆地质,2001,21(1):59-63.
宋会侠,刘玉琳,屈文俊,等.新疆包古图斑岩铜矿矿床地质特征[J].岩石学报,2007,23(8):1981-1988.
苏玉平,唐红峰.新疆西准噶尔达尔布特构造带铝质A型花岗岩的地球化学研究[J].地球化学,2006,35(1):55-67.
唐功建,王强,赵振华,等.西准噶尔包古图成矿斑岩年代学与地球化学:岩石成因与构造、铜金成矿意义[J].地球科学:中国地质大学学报,2009,34(1):56-74.
佟丽莉,李永军,张兵,等.新疆西准噶尔达尔布特断裂带南包古图组安山岩LA-ICP-MS锆石U-Pb测年及地质时代[J].新疆地质,2009,27(3):226-230.
涂光炽.初论中亚成矿域[J].地质科学,1999,34(4):397-404.
涂光炽.新疆北部固体地球科学进展[M].北京:地质出版社,1993.239.
王德滋,赵广涛,邱检生.中国东部晚中生代A型花岗岩的构造制约[J].高校地质学报,1995,1(2):13-21.
王强,赵振华,熊小林.桐柏—大别造山带燕山晚期A型花岗岩的厘定[J].岩石矿物学杂志,2000,19(4):297-306.
王有标,赵殿甲.中国新疆金矿床[M].北京:地质出版社,2006.66-161.
王中刚,朱笑青,毕华,等.中国新疆华岗岩[M].北京:地质出版社,2006.88-151,255-270.
吴淦国.新疆北部主要斑岩铜矿带[M].北京:地质出版社,2008,340.
吴福元,李献华,杨进辉,等.花岗岩成因研究的若干问题[J].岩石学报,2007,23(6):1217-1238.
吴锁平,王梅英,戚开静.A型花岗岩研究现状及其述评[J].岩石矿物学杂志2007,26(1):57-66.
吴元保,郑永飞.锆石成因矿物学研究及其对U-Pb年龄解释的制约[J].科学通报,2004,49(16):1589-1604.
伍建机,陈斌.西准噶尔庙尔沟后碰撞花岗岩微量元素和Nd-Sr同位素特征及成因[J].新疆地质,2004,22(1):29-35.
向坤鹏,李永军,徐磊,等.新疆西准噶尔包古图—哈图地区“太勒古拉组”使用商榷[J].新疆地质(待刊),2013.
肖庆辉,邓晋福,等.花岗岩研究思维与方法[M].北京:地质出版社,2002.53-63.
肖文交,韩春明,袁超,等.新疆北部石炭纪—二叠纪独特的构造—成矿作用:对古亚洲洋构造域南部大地构造演化的制约[J].岩石学报,2006,22(5):1062-1076.
肖文交,舒良树,高俊,等.中亚造山带大陆动力学过程与成矿作用[J].新疆地质,2008,26(1):4-8.
新疆维吾尔族自治区地质矿产局.新疆区域地质志[M].北京:地质出版社,1993.
新疆维吾尔族自治区地质矿产局.新疆维吾尔族自治区石地层[M].北京:中国地质大学出版社,1999.
新疆维吾尔族自治区地质矿产局区域地质调查大队.天山花岗岩地质[M].北京:地质出版社,1985.
许保良,阎国翰,张臣.A型花岗岩的岩石学亚类及其物质来源[J].地学前缘,1998,5(3):113-124.
严镜.新疆西准噶尔加甫沙尔苏花岗岩研究[D].西安:长安大学,2011.
杨富贵,刘丛强,王中刚.达拉布特型碱性花岗岩形成和演化的某些问题探讨[J].淄博学院学报(自然科学与工程版),1999,1(1):47–54.
杨富贵,王中刚,侯鸿泉.达尔布特型碱性花岗岩源岩特征初步探讨—来自稳定同位素和微量元素的证据[J].地质地球化学,1998(1):41-46.
杨富贵,王中刚,刘丛强,等.西北准噶尔地区碱性花岗岩体中角闪石的地质地球化学意义[J].矿物学报,1999,19(1):70–76.
杨富全,闫升好,刘国仁,等.新疆准噶尔斑岩铜矿地质特征及成矿作用[J].矿床地质,2010,29(6):956-971.
袁忠信.关于A型花岗岩命名问题的讨论[J].矿物岩石学杂志,2001,20(3):293-296.
张兵,康磊,李永军,等.新疆西准噶尔夏尔莆岩体中微粒镁铁质包体特征及其意义[J].新疆地质,2009,27(3):207–211.
张弛,黄萱.新疆西准噶尔蛇绿岩形成时代和环境的探讨[J].地质论评,1992,38(6):509-524.
张洪伟,康磊,赵春环,等.西准噶尔夏尔莆岩体岩浆混合的地球化学证据[J].西北地质,2011,44(2):41–50.
张连昌,万博,焦学军,等.西准包古图含铜斑岩的埃达克岩特征及其地质意义[J].中国地质,2006,33(3):626-631.
张良臣,刘德权,王有标,等.中国新疆优势金属矿产成矿规律[M].北京:地质出版社,2006.75-170,417-467.
张旗,秦克章,王元龙,等.加强埃达克岩研究,开创中国Cu、Au等找矿工作的新局面[J].岩石学报,2004,20(2):195-204.
张旗,王焰,钱青,等.中国东北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.
赵振华,白正华,熊小林,等.中国新疆北部富碱火成岩及其成矿作用[M].北京:地质出版社,2006.12-67,207-251.
赵振华,王中刚,邹天人,等.新疆乌伦古富碱侵入岩成因探讨[J].地球化学,1996,25(3):205-210.
中国科学院贵阳地球化学研究所.华南花岗岩的地球化学[M].北京:科学出版社,1979.
朱金初,张佩华,谢才富,等.南岭西段花山姑婆山A型花岗质杂岩:岩石学、地球化学和岩石成因[J].地质学报,2006,80(4):529-542.
朱志新,杨长文,李卫东等.艾肯能塔格韧性剪切带[J].新疆地质,2003,21(3):286-289.
朱训,黄崇柯,芮宗瑶.德兴斑岩铜矿[M].北京:地质出版社,1983.336.
朱永峰,何国琦,安芳.中亚成矿域核心地区地质演化与成矿规律[J].地质通报,2007,26(9):1167-1177.
朱永峰,王涛,徐新.新疆及邻区地质与矿产研究进展[J].岩石学报,2007,23(8):1785-1794.
Ballard J R,Palin J M and Williams I S. Two ages of porphyry intrusion resolved for the super-giantChuquicamata copper deposit of northern Chile by LA–ICP–MS and SHRIMP[J]. Geology,2001,9:383-386.
Barbarin B. A review of the relationships between granitoid type,their origins and their geodynamicenvironments[J]. Lithos,1999,46:605-626.
Bonin B. A-type granites and related rocks: Evolution of a concept,problems and prospects[J]. Lithos,2007,97:1-29.
Chappell B W and White A J R Wang,J B. Two Contrasting granite types[J]. Pac Geol,1974,8:173-174.
Chen Bo and Arakawa Y. Elemental and Nd-Sr isotopic geochemistry of granitoids from the West Junggarfoldbelt (NW China),with implications for Phanerozoic continental growth[J]. Geochimica etCosmochimica Acta.2005,69(5):1307-1320.
Chen Bo,Jahn B M. Genesis of post-collisional granitoids and basement nature of the Junggar Terrane,NWChina: Nd-Sr isotope and trace element evidence[J]. J Asian Earth Sci,2004,23(5):691-703.
Collins W J,Beams S D,White A R and Chappell B W. Nature and origin of A-type granites with particularreference to southeastern Australia[J]. Contrib Mineral Petrol,1982,80:189-200.
Compston W,Williams I S,Kirschvink J L et a1. Zircon U-Pb ages for the Early Cambrian time-scale[J].Joumal of GeologicalSociety,1992,149:171-184.
Creaser R A,Price R C and Wormald R J. A-type granites revisited:Assessment of a residual-sourcemodel[J]. Geology,1991,19:163-166.
Defant MJ and Drummond MS. Derivation of some modern arc magmas by melting of young subductedlithosphere[J]. Nature,1990,34:662-665.
Defant MJ and Kepezhinskas P. Evidence suggests slab melting in arc magmas[J]. EOS,2001,82(6):67-69.
Eby G N. Chemical subdivision of the A-type granitoids:Petrogenetic and tectonic implications[J].Geology,1992,20:641-644.
Eby G N. The A-type granitoids:A review of their occurrence and chemical characteristics and speculationson their petrogenesis[J]. Lithos,1990,26:115-134.
Feng Yi-ming M,Coleman,R G,Tilton,G R. Tectonic evolution of the West Junggar region,Xinjiang,China[J]. Tectonics,1989,8:729-752.
Frost C D and Frost B R. Reduced rapakivi-type granites: The tholeiite connection[J]. Geology,1997,25:647-650.
Frost C D,Frost B R,Chamberlain K R,et a1. Petrogenesis of the143Ga Sherman batholith,SE Wyoming,USA: A reduced,rapakivi-type anorogenic granite[J]. J Petrol,1999,40:1771-1802.
Geng HY,Sun M,Yuan C,Xiao WJ,et a1. Geochemical,Sr–Nd and zircon U–Pb–Hf isotopic studies ofLate Carboniferous magmatism in the West Junggar,Xinjiang: Implications for ridge subduction?[J].Chemical Geology,2009,266(3-4):364-389.
Gaoxue Yang,Yongjun Li,M. Santosh,et al. Geochronology and geochemistry of basaltic rocks from theSartuohai ophiolitic mélange,NW China: Implications for a Devonian mantle plume within theJunggar Ocean. Journal of Asian Earth Sciences[J]. Journal of Asian Earth Sciences,2012,59:141-155.
Han Baofu,Wang S G,Jahn B M,et a1. Depleted-mantle source for the Ulungur River A-type granites fromNorth Xinjiang,China:Geochemistry and Nd-Sr isotopic evidence. and implications for Phanerozoiccrustal growth[J]. Chemical Geology,1997,138:135-159.
Harris C. The petrology of lavas and associated plutonic inclusions of Ascension Island[J]. J Petrol,1983,24:424-470.
King P L,Chappell B W and White A J R Are. A-type granites the high-temperature felsic grenites Evidencefrom fractionated granites of the Wangrah Suite[J]. Aust J Earth Sci,2001,48:501-514.
King P L,White A J R and Chappell B W. Characterization and origin of A-type granites of the LachlanFold Belt,southeastern Australia[J]. J Petrol,1997,36:371-391.
Kwon S T,Tilton G R,Coleman R G,et a1. Isotopic studies bearing on the tectonics of the West Junggarregion,Xinjiang,China[J]. Tectonics,1989,8(4):719-727.
Liu Xioa-ming,Gao S,Yuan HL,et a1. Analysis of42major and trace elements in glass standard referencematerials by193nm LA-ICP-MS[J]. Acta Petrologica Sinica,2002,18(3):408–418.
Liu YL,Guo LS,Liu YD,et a1. Geochronology of Baogutu porphyry copper deposit in Western Junggararea,Xinjiang of China[J]. Science in China Series D: Earth Sciences,2009,52(10):1543-1549.
Loiselle M C and Wones D R. Characteristics and origin of anorogenic granites[J]. Geol Soc Am Bull,1979,11:468.
Ludwig K R. Isoplot-A plotting and regression program for radiogenic-isotope data[R]. US GeologicalSurvey Open-File Report,1991,39:91-445.
Maniar P D and Picooli P M. Tectonic discrimination of granitoids[J]. Geol Soc Am Bull,1989,101:635-643.
Pearce J A,Harris N B W and Tindle A G. Trace element discrimination diagrams for tectonic interpretationof granitic rock[J]. J Petrol,1984,25:956-983.
Pidgeon R T,Nemchin A A,Hitchen G J. Internal structures of zircons from Archaean granites from heDarling Range batholith:implications for zircon stability and the interpretation of zircon U-Pb ages[J].Contributions to Mineralogy and Petrology,1998,132:288-299.
Rogers J J W and Greenberg J E. Late-orogenic,post-orogenic,and anorogenic granites: Distinction bymajor-element and trace-element chemistry and possible origins[J]. J Geol,1990,98:291-310.
Seltmann R and Porter TM. The Porphyry Cu-Au/Mo Deposits of Central Eurasia:1. Tectonic,Geologic&Metallogenic Setting and Significant Deposits[J].(in)Porter T M(eds) Super Porphyry Copper&Gold Deposits-A Global Perspective,PGC Publishing,2005,2:467-511.
Shen,P,Shen,Y C,Liu,T B,et al. Geochemical signature of porphyries in the Baogutu porphyry copperbelt,western Junggar,NW China[J]. Gondwana Research,2009,16:227-242.
Shen,P,Shen,Y C,Wang,J B,et al. Methane-rich fluid evolution of the Baogutu porphyry Cu–Mo–Audeposit,Xinjiang,NW China[J]. Chemical Geology,2010,275:78-98.
Shen,P,Shen,Y,Li,X H. Northwest Junggar,Xiemisitai Mountains,China: A geochemical andgeochronological approach[J]. Lithos,2012,141:103-118.
Sillitoe RH. Characteristics and controls of the largest porphyry copper‐gold and epithermal gold depositsin the circum‐Pacific region[J]. Australian Journal of Earth Sciences,1997,44(3):373-388.
Sillitoe Richard H. A Plate Tectonic Model for the Origin of Porphyry Copper Deposits[J]. EconomicGeology,1972,67(2):184-197.
Sillitoe Richard H and Mortensen James K. Longevity of porphyry copper formation at quellaveco,Peru[J].Economic Geology,2010,105(6):1157-1162.
Staudigel H,Davies G R,Hart S R,et a1. Large scale isotopic Sr,Nd and O isotopic anatomy of alteredoceanic crust: DSDP/ODP sites417/418[J]. Earth Planet SciLett,1995,130(1/4):169-185.
Sun SS and McDonough WF. Chemical and isotopic systematics of oceanic basalts: implications for mantlecomposition and process s. In: Sauders AD and Norry MJ(eds). Magmatism in the OceanBasins[J].Geological Society. Special Publication,1989,42:3l3-345.
Tang GJ,Wang Q,Wyman DA,et a1. Ridge subduction and crustal growth in the Central Asian OrogenicBelt: Evidence from Late Carboniferous adakites and high-Mg diorites in the western Junggar region,northern Xinjiang (west China)[J]. Chemical Geology,2010,277(3-4):281-300.
Turner S P,Foden J D and Morrison R S. Derivation of some A-type magmas by fractionation of basalticmagama: an example from the Padthaway Ridge,South Australia[J].Lithos,1992,28:151-179.
Wang Q,Zhao Z H,Xu J F,et al. Carboniferous adakite-high-Mg andesite-Nb-enriched basaltic rock suitesin the Northern Tianshan area:Implications for Phanerozoic crustal growth in the Central Asia OrogenicBelt and Cu-Au mineralization[J]. Acta Petrologica Sinica,2006,22(1):11-30.
Whalen J B,Currie K and Chappell. B W. A-type granites:geochemical characteristics,dirimination andpetrogenesis[J]. Contrib,Minera1,Petro1,1987,95:407-419.
Xiao,W J,Han,C M Yuan,C,et al. Middle Cambrian to Permian subduction-related accretionaryorogenesis of North Xinjiang,NW China: implications for the tectonic evolution of Central Asia[J].Journal of Asian Earth Sciences,2008,32:102-117.
Xiao,WJ,Huang,BC,Han,CM,et al. A review of the western part of the Altaids: A key to understandingthe architecture of accretionary orogens[J]. Gondwana Research,2010,18:253-273.
Xiao,W J,Kusky,T M. Geodynamic processes and metallogenesis of the Central Asian and relatedorogenic belts: introduction[J]. Gondwana Research,2009,16:167-169.
Xiao,W J,Windley,B F,Badarch,G,et al. Palaeozoic accretionary and convergent tectonics of thesouthern Altaids: implications for the lateral growth of Central Asia[J]. Journal of the GeologicalSociety,London,2004,161:339-342.
Xiao,W J,Windley,B F,Yuan,C,et al. Paleozoic multiple subduction-accretion processes of the southernaltaids[J]. American Journal of Science,2009,309:221-270.
Yang J H,Wu F Y,Chung S L,et al. A hybrid origin for the Qianshan A-type granite,northeast China:Geochemical and Sr-Nd-Hf isotopic evidence[J]. Lithos,2006,89:89-106.
Yin JY,Yuan C,Sun M,et al. Late Carboniferous high-Mg dioritic dikes in Western Junggar,NW China:Geochemical features,petrogenesis and tectonic implications[J]. Gondwana Research,2010,17(1):145-152.
P.亨德森主编.稀土元素地球化学[M].北京:地质出版社,1989.20-178.
北京大学地质系编.斑岩铜矿及其找矿[M].北京:冶金工业出版社,1978.159.
成守德,王广瑞,杨树德,等.新疆古板块构造[J].新疆地质,1986,4(2):1-26.
成守德,王元龙.新疆大地构造演化基本特征[J].新疆地质,1998,16(2):97-107.
成守德,王元龙.中亚地壳发展演化与成矿[M].乌鲁木齐:新疆人民出版社,2000.
陈毓川,裴荣富,王登红.三论矿床的成矿系列问题[J],地质学报,2006a,80(10):1501-1508.
陈毓川,王登红,徐志刚,等.对中国成矿体系的初步探讨[J].矿床地质,2006b,25(2):155-163.
董连慧,冯京,李凤鸣.2004年新疆地质矿产勘查进展及2005年工作思路[J].新疆地质,2005,23(1):1-3.
董连慧,冯京,李凤鸣.新疆非油气矿产地质勘查“十五”主要成果及“十一五”地质找矿重点[J].新疆地质,2006c,24(1):1-3.
董连慧,冯京,刘德权等,新疆成矿单元划分方案研究[J].新疆地质,2010a,28(1):1-15.
董连慧,李凤鸣,屈迅.2008年新疆地质矿产勘查主要成果及国土资源部与新疆维吾尔自治区“358项目”工作部署[J].新疆地质,2009a,27(1):1-4.
董连慧,屈迅,朱志新,张良臣.新疆大地构造演化与成矿[J].新疆地质,2010b,28(4):351-357.
董连慧,徐兴旺,屈迅,李光明.初论环准噶尔斑岩铜矿带的地质构造背景与形成机制[J].岩石学报,2009b,25(4):713-737.
杜琦.斑岩铜矿成因探讨[M].北京:地质出版社,2008.91.
冯京,徐仕琪,赵青,等.新疆斑岩型铜矿成矿规律及找矿方向[J].新疆地质.2010,28(1):43-51.
高合明.德兴斑岩铜矿床成矿作用动力学与成矿作用复杂性[M].北京:原子能出版社,1999.89.
高山林,何治亮,周祖翼.西准噶尔克拉玛依花岗岩体地球化学特征及其意义[J].新疆地质,2006,24(2):125–130.
辜平阳,李永军,王晓刚,等.西准噶尔达尔布特SSZ型蛇绿杂岩的地球化学证据及构造意义[J].地质论评,2011,57(1):36-44.
辜平阳,李永军,张兵,等.西准达尔布特蛇绿岩中辉长岩LA-ICP-MS锆石U-Pb测年[J].岩石学报,2009,25(6):1364-1372.
韩宝福,季建清,宋彪,等.新疆准噶尔晚古生代陆壳垂向生长(I):后碰撞深成岩浆活动的时限[J].岩石学报,2006,22(5):1077–1086.
韩宝福,何国琦,王式洸.后碰撞岩浆活动、底垫作用及准噶尔盆地基底的性质[J].中国科学(D辑),1999,29(1):16-21.
韩宝福,何国琦,王式洸,等.新疆北部后碰撞幔源岩浆活动与陆壳纵生长[J].地质论评,1998a,44(4):396-406.
韩宝福,何国琦,吴泰然,等.天山早古生代花岗岩锆石U-Pb定年、岩石地球化学特征及其大地构造意义[J].新疆地质,2004,22(1):4-11.
韩宝福,王式洸,等.新疆乌伦古河碱性花岗岩Nd同位素特征及其对显生宙地壳生长的意义[J].科学通报,1997,42(17):1829-1832.
韩宝福,王式洗,孙元林,等.正εNd(t)值的准铝-过铝花岗岩:新疆也布山岩体[J].科学通报,1998b,43(12):1324-1328.
何国琦,朱永峰.中国新疆及其邻区地质矿产对比研究[J].中国地质,2006,33(3):451-460.
何晓刚,康磊,王晓刚,等.西准噶尔夏尔莆岩体岩浆混合的岩石化学证据[J].新疆地质,2011,29(3):251–256.
贺敬博,陈斌.西准噶尔克拉玛依岩体的成因:年代学、岩石学和地球化学证据[J].地学前缘,2011,18(2):191-211.
洪大卫,王式洸,韩宝福,等.碱性花岗岩的构造环境分类及其鉴别标志[J].中国科学(B辑),1995,25(4):418-426.
洪大卫,王式洸,谢锡林等.兴蒙造山带正εNd(t)值花岗岩的成因和大陆地壳生长[J].地学前缘,2000,7(2):441-455.
洪大卫,王涛,童英.中国花岗岩概述[J].地质论评,2007,53,增刊:9-16.
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):131-144.
侯增谦.大陆碰撞成矿论[J].地质学报,2010,84(1):30-58.
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.
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,2003b,22(1):319-333.
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,2003a,22(1):1-22.
侯增谦,杨志明.中国大陆环境斑岩型矿床:基本地质特征、岩浆热液系统和成矿概念模型[J].地质学报,2009,83(12):1779-1816.
贾小辉,王强,唐功建.A型花岗岩的研究进展及意义[J].大地构造与成矿学,2009,33(3):465-480.
简伟,柳维,石黎红.斑岩型钼矿床研究进展[J].矿床地质,2010,29(2):308-316.
金成伟,张秀棋.新疆西准噶尔花岗岩类的时代及其成因[J].地质科学,1993,28(1):28–36.
康磊.新疆西准噶尔夏尔莆岩浆混合花岗岩体的研究[D].西安:长安大学,2010.
康磊,李永军,张兵,等.新疆西准噶尔夏尔莆岩体岩浆混合的岩相学证据[J].岩石矿物学杂志,2009,28(5):423-432.
李昌年.岩浆混合作用及其研究评述[J].地质科技情报,2002,21(4):49–54.
李华芹,陈富文.中国新疆区域成矿作用年代学[M].北京:地质出版社,2004.11-15,83-217,259-276.
李锦轶,肖序常.对新疆地壳结构与演化几个问题的简单评述[J].地质科学,1999,34(4):405-419.
李卫东,付延龙,李文铅.鲍尔羌吉韧变花岗岩类地质特征[J].新疆地质,2000,18(2):129-135.
李卫东,彭湘萍,康正文等.东昆仑木孜塔格地区畅流沟蛇绿岩岩石地球化学特征及其构造意义[J].新疆地质,2003,21(3):263-268.
李卫东,涂其军,高永峰等.新疆哈密市路白山一带片麻状花岗岩锆石SHRIMP U-Pb定年及其地质意义[J].中国地质,2010,37(5):1273-1283.
李卫东,王晓东,范新丽.东准噶尔鲍尔羌吉一带热隆伸展构造的厘定[J].新疆地质,2002,20(1):29-33.
李卫东,周继兵,李永军等.西天山特克斯达坂岩基解体的地球化学证据及钼找矿意义[J].岩石矿物学杂志,2008,27(5):405-412.
李辛子,韩宝福,季建清,等.新疆克拉玛依中基性岩墙群的地质地球化学和K-Ar年代学[J].地球化学,2004,33(6):574-584.
李永军,王冉,李卫东,等.西准达尔布特南构造岩浆岩带斑岩型铜-钼矿新发现及找矿思路[J].岩石学报,2012,28(7):2009-2014.
李永军,佟丽莉,张兵,等.论西准噶尔石炭系希贝库拉斯组与包古图组的新老关系[J].新疆地质,2010,28(2):130–136.
李辛子,韩宝福,季建清,等.新疆克拉玛依中基性岩墙群的地质地球化学和K-Ar年代学[J].地球化学,2004,33(6):574–584.
李宗怀,韩宝福,李辛子,等.新疆准噶尔地区花岗岩中微粒闪长质包体特征及后碰撞花岗质岩浆起源和演化[J].岩石矿物学杂志,2004,23(3):214–226.
刘宝良. CIPW标准矿物计算法应用时存在问题的探讨[J].地质与资源,2001,10(3):180-189.
刘德权,唐延龄,周汝洪.中国新疆矿床成矿系列[M].北京,地质出版社,1996.11-15,83-217,259-276.
刘德权,唐延龄,周汝洪,等.中国新疆铜矿床和镍矿床[M].北京:地质出版社,2005.11-15,177-245.
马铁球,伍光英,贾宝华,等.南岭中段郴州一带中、晚侏罗世花岗岩浆的混合作用—来自镁铁质微粒包体的证据[J].地质通报,2005,24(1):506–512.
庞振甲,李永军,赵玉梅,等.西准阿克巴斯陶铝质A型花岗岩厘定及意义[J].新疆地质,2010,28(2):119-124(in Chinese with English abstract).
邱检生,王德滋,蟹泽聪史,等.福建沿海铝质A型花岗岩的地球化学及岩石成因[J].地球化学,2000,29(4):313-321.
芮宗瑶.中国斑岩铜(钼)矿床[M].北京:地质出版社,1984.350.
申萍,沈远超.西准噶尔与环巴尔喀什斑岩型铜矿床成矿条件及成矿模式对比研究[J].岩石学报,2010,26(8):2299-2316.
沈远超,金成伟.西准噶尔地区岩浆活动与金矿化作用[M].北京:科学出版社,1993.113-171.
舒良树,卢华复,印栋浩,等.新疆北部古生代大陆增生构造[J].新疆地质,2001,21(1):59-63.
宋会侠,刘玉琳,屈文俊,等.新疆包古图斑岩铜矿矿床地质特征[J].岩石学报,2007,23(8):1981-1988.
苏玉平,唐红峰.新疆西准噶尔达尔布特构造带铝质A型花岗岩的地球化学研究[J].地球化学,2006,35(1):55-67.
唐功建,王强,赵振华,等.西准噶尔包古图成矿斑岩年代学与地球化学:岩石成因与构造、铜金成矿意义[J].地球科学:中国地质大学学报,2009,34(1):56-74.
佟丽莉,李永军,张兵,等.新疆西准噶尔达尔布特断裂带南包古图组安山岩LA-ICP-MS锆石U-Pb测年及地质时代[J].新疆地质,2009,27(3):226-230.
涂光炽.初论中亚成矿域[J].地质科学,1999,34(4):397-404.
涂光炽.新疆北部固体地球科学进展[M].北京:地质出版社,1993.239.
王德滋,赵广涛,邱检生.中国东部晚中生代A型花岗岩的构造制约[J].高校地质学报,1995,1(2):13-21.
王强,赵振华,熊小林.桐柏—大别造山带燕山晚期A型花岗岩的厘定[J].岩石矿物学杂志,2000,19(4):297-306.
王有标,赵殿甲.中国新疆金矿床[M].北京:地质出版社,2006.66-161.
王中刚,朱笑青,毕华,等.中国新疆华岗岩[M].北京:地质出版社,2006.88-151,255-270.
吴淦国.新疆北部主要斑岩铜矿带[M].北京:地质出版社,2008,340.
吴福元,李献华,杨进辉,等.花岗岩成因研究的若干问题[J].岩石学报,2007,23(6):1217-1238.
吴锁平,王梅英,戚开静.A型花岗岩研究现状及其述评[J].岩石矿物学杂志2007,26(1):57-66.
吴元保,郑永飞.锆石成因矿物学研究及其对U-Pb年龄解释的制约[J].科学通报,2004,49(16):1589-1604.
伍建机,陈斌.西准噶尔庙尔沟后碰撞花岗岩微量元素和Nd-Sr同位素特征及成因[J].新疆地质,2004,22(1):29-35.
向坤鹏,李永军,徐磊,等.新疆西准噶尔包古图—哈图地区“太勒古拉组”使用商榷[J].新疆地质(待刊),2013.
肖庆辉,邓晋福,等.花岗岩研究思维与方法[M].北京:地质出版社,2002.53-63.
肖文交,韩春明,袁超,等.新疆北部石炭纪—二叠纪独特的构造—成矿作用:对古亚洲洋构造域南部大地构造演化的制约[J].岩石学报,2006,22(5):1062-1076.
肖文交,舒良树,高俊,等.中亚造山带大陆动力学过程与成矿作用[J].新疆地质,2008,26(1):4-8.
新疆维吾尔族自治区地质矿产局.新疆区域地质志[M].北京:地质出版社,1993.
新疆维吾尔族自治区地质矿产局.新疆维吾尔族自治区石地层[M].北京:中国地质大学出版社,1999.
新疆维吾尔族自治区地质矿产局区域地质调查大队.天山花岗岩地质[M].北京:地质出版社,1985.
许保良,阎国翰,张臣.A型花岗岩的岩石学亚类及其物质来源[J].地学前缘,1998,5(3):113-124.
严镜.新疆西准噶尔加甫沙尔苏花岗岩研究[D].西安:长安大学,2011.
杨富贵,刘丛强,王中刚.达拉布特型碱性花岗岩形成和演化的某些问题探讨[J].淄博学院学报(自然科学与工程版),1999,1(1):47–54.
杨富贵,王中刚,侯鸿泉.达尔布特型碱性花岗岩源岩特征初步探讨—来自稳定同位素和微量元素的证据[J].地质地球化学,1998(1):41-46.
杨富贵,王中刚,刘丛强,等.西北准噶尔地区碱性花岗岩体中角闪石的地质地球化学意义[J].矿物学报,1999,19(1):70–76.
杨富全,闫升好,刘国仁,等.新疆准噶尔斑岩铜矿地质特征及成矿作用[J].矿床地质,2010,29(6):956-971.
袁忠信.关于A型花岗岩命名问题的讨论[J].矿物岩石学杂志,2001,20(3):293-296.
张兵,康磊,李永军,等.新疆西准噶尔夏尔莆岩体中微粒镁铁质包体特征及其意义[J].新疆地质,2009,27(3):207–211.
张弛,黄萱.新疆西准噶尔蛇绿岩形成时代和环境的探讨[J].地质论评,1992,38(6):509-524.
张洪伟,康磊,赵春环,等.西准噶尔夏尔莆岩体岩浆混合的地球化学证据[J].西北地质,2011,44(2):41–50.
张连昌,万博,焦学军,等.西准包古图含铜斑岩的埃达克岩特征及其地质意义[J].中国地质,2006,33(3):626-631.
张良臣,刘德权,王有标,等.中国新疆优势金属矿产成矿规律[M].北京:地质出版社,2006.75-170,417-467.
张旗,秦克章,王元龙,等.加强埃达克岩研究,开创中国Cu、Au等找矿工作的新局面[J].岩石学报,2004,20(2):195-204.
张旗,王焰,钱青,等.中国东北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.
赵振华,白正华,熊小林,等.中国新疆北部富碱火成岩及其成矿作用[M].北京:地质出版社,2006.12-67,207-251.
赵振华,王中刚,邹天人,等.新疆乌伦古富碱侵入岩成因探讨[J].地球化学,1996,25(3):205-210.
中国科学院贵阳地球化学研究所.华南花岗岩的地球化学[M].北京:科学出版社,1979.
朱金初,张佩华,谢才富,等.南岭西段花山姑婆山A型花岗质杂岩:岩石学、地球化学和岩石成因[J].地质学报,2006,80(4):529-542.
朱志新,杨长文,李卫东等.艾肯能塔格韧性剪切带[J].新疆地质,2003,21(3):286-289.
朱训,黄崇柯,芮宗瑶.德兴斑岩铜矿[M].北京:地质出版社,1983.336.
朱永峰,何国琦,安芳.中亚成矿域核心地区地质演化与成矿规律[J].地质通报,2007,26(9):1167-1177.
朱永峰,王涛,徐新.新疆及邻区地质与矿产研究进展[J].岩石学报,2007,23(8):1785-1794.
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