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1.
选取西藏冈底斯成矿带的驱龙、达布斑岩型铜钼矿及鸡公村石英脉型钼矿为研究对象,分别挑选含矿斑岩和石英脉中的黄铜矿、辉钼矿进行Cu、Mo同位素测定.结果表明,西藏冈底斯斑岩型黄铜矿的δ^65/63Cu介于0.01‰~0.98‰,辉钼矿的δ^97/95Mo介于-0.34‰^-0.15‰,热液脉型矿床中辉钼矿的δ^97/95Mo介于-0.35‰^-0.23‰.形成于陆-陆碰撞造山后的冈底斯斑岩型铜钼矿床的Cu同位素与俯冲带产出的斑岩型矿床中的Cu同位素组成具有一定的相似性,均表现为单峰分布的特征.驱龙斑岩型矿床中热液脉与含矿斑岩中的δ^65/63Cu具有一致性,可能反映了二者在来源上具有一致性.在冈底斯斑岩型铜钼矿床中,不同蚀变带具有不同的Cu、Mo同位素组成,自蚀变中心向外,δ^65/63Cu与δ^97/95Mo表现出负相关趋势,可能与成矿流体的性质密切相关.冈底斯石英脉型钼矿较斑岩型铜钼矿δ^97/95Mo相对偏负,结合两类矿床的成矿年代,可能暗示两类矿床的成矿物质是同一源区连续演化的结果. 相似文献
2.
内蒙古鸡冠山钼矿床位于中亚-蒙古巨型造山带东段,是西拉沐沦钼金属成矿带中典型的大型斑岩型钼矿床。矿床产于燕山晚期火山侵入杂岩中,矿体与岩体关系密切,矿化类型以细脉浸染状斑岩型矿化为主。在野外地质观察的基础上,本文对矿石矿物黄铁矿、辉钼矿进行了S同位素组成分析,对矿床围岩全岩及黄铁矿单矿物进行了Pb同位素组成分析。结果表明,钼矿石δ~(34)S变化范围为4. 617‰~7. 072‰,平均值为5. 653‰,离散度小,硫化物δ~(34)S值全为正值,表明矿石中S源是均一的。辉钼矿δ~(34)S变化范围为4. 617‰~5. 351‰,平均值为4. 875‰。硫同位素比值5. 653‰具花岗质岩浆硫特征,推测其硫可能主要来源于下地壳岩浆源,并有一定量的地幔物质混入。全岩的~(206)Pb/~(204)Pb、~(207)Pb/~(204)Pb和~(208)Pb/~(204)Pb分别为17. 876~19. 618、15. 519~15. 609和38. 111~40. 408,表明鸡冠山钼矿床围岩的全岩铅同位素组成均变化较大。矿石矿物黄铁矿的~(206)Pb/~(204)Pb、~(207)Pb/~(204)Pb和~(208)Pb/~(20 4)Pb分别为17. 781~17. 830、15. 523~15. 526和38. 084~38. 102,表明矿石矿物铅同位素组成变化较小。围岩全岩和矿石硫化物的铅同位素投影点均落在造山带演化线的下方,表明铅很可能源于地幔或者下地壳。 相似文献
3.
查个勒铅锌钼铜矿床位于念青唐古拉铅锌银铁铜成矿带西段南缘,为查明其成矿物质来源及矿床成因,对该矿床开展了系统的H、O、S、Pb同位素研究,并与念青唐古拉成矿带中-东段典型铅锌(铜钼)矿床进行对比。查个勒矿床石英H、O同位素(δD值介于-189‰~-157‰之间,δ~(18)O_(H_2O)值介于-2.2‰~2.9‰之间)指示其成矿流体主要由岩浆水与大气降水混合组成。矿区北部铅锌矿体硫化物δ~(34)S值为-5.6‰~-0.8‰,均值为-3.7‰,显示岩浆硫和地层硫混合的特征。矿区南部(铜)钼矿体硫化物δ~(34)S值为1.1‰~2.6‰,均值为1.8‰,显示岩浆硫的特征。矿石硫化物和花岗斑岩全岩~(208)Pb/~(204)Pb,~(207)Pb/~(204)Pb,~(206)Pb/~(204)Pb的比值分别为38.988~39.269、39.002~39.559,15.657~15.747、15.643~15.664,18.614~18.688、18.663~19.058。矿石硫化物与花岗斑岩的Pb同位素特征相似,均表现出上地壳Pb源的特征,推测成矿物质主要来自上地壳岩浆源。查个勒矿床H、O、S、Pb同位素特征与中-东段典型铅锌(铜钼)矿床相似,表明念青唐古拉成矿带铅锌(铜钼)矿床成矿流体及成矿物质来源一致。作者认为查个勒矿床是一个受岩浆和构造共同控制的斑岩型(铜)钼+矽卡岩型-热液脉型铜铅锌矿床,在念青唐古拉成矿带,自西向东分布有多处斑岩型(铜)钼矿+矽卡岩型-热液脉型(铜)铅锌矿矿集区。 相似文献
4.
河南省新县大银尖钼矿床同位素地球化学研究 总被引:2,自引:0,他引:2
在详细的野外地质工作基础上,本文测定了河南省新县大银尖钼矿床的矿石硫、铅同位素,含矿石英脉中石英的氧同位素、石英中包裹体的氢同位素组成,以及辉钼矿的铼含量,参照前人的研究成果,探讨大银尖钼矿床成矿物质来源和形成机制.矿石硫同位素δ34SV-CDT介于3.90‰~ 10.70‰之间,均值为7.44‰.矿石铅同位素n(206Pb) /n(204Pb)介于17.0411~17.3188之间,均值为17.1388;n(207pb)/n(204Pb)介于15.3968~ 15.4166之间,均值为15.4041;n(208Pb)/n(204Pb)介于37.7322 ~38.2360之间,均值为37.9100.含矿石英脉中石英的δ18 OSMOW值在11.20‰~13.20‰之间,均值为11.90‰;石英中包裹体的δDSMOW介于-79.00‰ ~-76.90‰之间,均值为-78.28‰;利用流体包裹体均一温度的平均值和Clayton平衡分馏方程计算与石英平衡共存流体的δ18OH2O,SMOw介于-0.26‰~3.70‰之间,均值为1.82‰.辉钼矿中的Re含量介于8.28×10-6~54.74×10-6之间.矿石硫同位素组成研究表明成矿物质与岩浆作用有关,但混有地壳物质.铅同位素组成和辉钼矿的铼含量研究表明,大银尖钼矿床的成矿物质主要来自地壳.含矿石英脉的氢和氧同位素组成研究显示,氧同位素飘离岩浆水范围,表明成矿流体早期为岩浆水,晚期混入大气降水,也进一步证实混合作用是大银尖钼矿形成的一种重要机制. 相似文献
5.
湖南黄沙坪铅锌多金属矿床铅、硫同位素地球化学特征 总被引:7,自引:0,他引:7
黄沙坪铅锌多金属矿床是湘南的代表性矿床之一, 矿床受SN向宝岭倒转背斜和观音打座倒转背斜的控制,赋存围岩以花岗斑岩与石英斑岩为主,矿石以铅锌硫化物矿石为主,对该矿床S同位素研究表明,δ34S值为-2.2‰~17.2‰。矿石Pb同位素组成206Pb/204Pb为17.893~18.772; 207Pb/204Pb为15.580~16.045;208Pb/204Pb为38.490~41.560。研究表明,该矿床的硫源可能是岩浆来源与海水(地层)硫混合作用形成;矿床中异常铅矿化的铅是岩源来源。 相似文献
6.
北达巴特斑岩型铜钼矿床位于西天山造山带北部。矿区钼矿化分布于流纹斑岩体内部,铜矿化受断裂构造控制,分布于流纹斑岩与地层的接触带附近。据矿物组合特征与交代关系,将成矿过程划分为3个阶段:早期石英—辉钼矿阶段,中期黄铁矿—黄铜矿—石英阶段,晚期萤石—黄铜矿阶段。对早阶段辉钼矿与晚阶段黄铜矿分别进行了Pb同位素分析。辉钼矿的208Pb/204Pb值为38.125~38.179,207Pb/204Pb值为15.570~15.575,206Pb/204Pb值为18.293~18.311,Pb同位素构造判别投点落在地壳和地幔范围内,有向造山带线靠近的趋势,指示成矿物质主要来源于地幔,流纹斑岩提供了主要的钼来源。黄铜矿208Pb/204Pb值为38.202~38.257,207Pb/204Pb值为15.581~15.621,206Pb/204 相似文献
7.
西藏冈底斯成矿带铅锌银矿床的S、Pb同位素组成及其地质意义 总被引:3,自引:1,他引:3
位于冈底斯斑岩铜矿带北侧的铅锌银矿化带是冈底斯成矿带的重要组成部分,具有巨大的成矿潜力。对冈底斯北侧铅锌银矿带的3个典型矿床进行的矿石矿物S、Pb同位素组成分析显示,各个矿床的金属硫化物的S同位素组成比较一致,δ34S为-3.9‰~-1.1‰,均值-2.42‰,与冈底斯斑岩铜矿床的S同位素组成接近。3个矿床矿石矿物的206Pb/204Pb范围为18.51523~19.76144,207Pb/204Pb变化于15.56129~15.85036之间,208Pb/204P介于38.50412~40.29409之间。3个铅锌银矿床的Pb同位素组成变化较大,可能指示它们具有不同的起源。在铅构造模式图上多偏离造山带Pb演化曲线而靠近上地壳Pb演化线。3个铅锌矿床的S、Pb同位素数据暗示,成矿物质主要来自上部地壳,具有复杂的演化历史。 相似文献
8.
大兴安岭北段岔路口和大黑山斑岩型钼矿床硫、铅同位素特征 总被引:1,自引:0,他引:1
岔路口和大黑山钼矿床位于大兴安岭北段,是近年来新发现的2个斑岩型钼矿床。文章通过对这2个矿床的硫、铅同位素的研究,探讨了成矿物质来源。岔路口矿区硫化物的δ34S值为1.8‰~2.9‰,平均2.4‰;大黑山矿区硫化物的δ34S值变化于0.4‰~2.3‰,平均1.53‰,均显示出典型的岩浆硫特征。岔路口矿区硫化物的206Pb/204Pb、207Pb/204Pb和208Pb/204Pb值分别变化于18.311~18.356、15.536~15.573和38.115~38.229,大黑山矿区硫化物的206Pb/204Pb、207Pb/204Pb和208Pb/204Pb值则分别变化于18.341~18.719、15.529~15.637和38.033~38.363。铅同位素进一步指示铅的来源与燕山期岩浆作用有关。在铅同位素构造模式图中,矿石铅主要投点于地幔演化线和造山带演化线之间,表明铅来自于壳幔物质的混合。大兴安岭北段在晚侏罗世受古太平洋板块俯冲的影响,发生了强烈的壳、幔相互作用并产生了大量含钼岩浆,为该区斑岩型钼矿床的形成奠定了基础。 相似文献
9.
治岭头矿床上部(火山岩盖层)以铅锌矿床、硫矿床为主,中间(变质岩基底)以金银矿、铅锌矿为主,深部(侵入岩体)以斑岩型钼矿床为主的"三层楼"模式。本文在前人研究的基础上,通过辉钼矿Re-Os同位素定年技术对治岭头矿床进行了成矿时代的厘定。6件辉钼矿样品的模式年龄为113.7~114.6 Ma,加权平均年龄为114.03±1.78 Ma,表明治岭头钼多金属矿床成矿作用发生于早白垩世晚期。该矿床辉钼矿样品的Re含量变化于16.05×10~(-6)~66.29×10~(-6),表明其成矿物质具有壳幔混源的特征。矿石硫同位素组成变化范围较窄(-2.1‰~2.6‰),具有相对均一的来源,可能主要来自上地幔或下地壳的深源岩浆,但也可能受到陆壳沉积物的混染。治岭头钼铅锌金多金属矿床矿石铅同位素组成变化范围比较小,~(208)Pb/~(204)Pb、~(207)Pb/~(204)Pb、~(206)Pb/~(204)Pb的范围分别为38.765~39.137、15.523~15.751、18.450~18.667,具有明显的壳幔混合特征。治岭头钼多金属矿床成矿年龄的厘定为下一步在区内开展同时期的斑岩成矿系统找矿勘探提供了重要的线索,同时为进一步深入研究中国东南沿海大陆边缘成矿带成岩成矿作用提供了新的资料和证据。 相似文献
10.
水竹岭铜-铁-金-硫矿床发育上部层状矿体和下部脉状矿体。上部层状矿石重晶石δ34S值为+19.9‰。上部层状矿石黄铁矿δ34S值为+0.9~+5.8‰,下部脉状矿石黄铁矿δ34S值为+3.2~+6.4‰。下部脉状矿体中方解石的δ18O值为+13.3‰,δ13C值为1.2‰,上部层状矿石白云石的δ18O值为+14.1‰,δ13C值为2.2‰。下部脉状矿石和矿化岩石中黄铁矿的206Pb/204Pb、207Pb/204Pb、208Pb/204Pb平均值分别为18.2241、15.5245和38.2289;上部层状矿石中黄铁矿的206Pb/204Pb、207Pb/204Pb、208Pb/204Pb平均值分别为18.0692、15.5020和38.1232。从下部脉状矿石到上部层状矿石,黄铁矿的δ34S值、206Pb/204Pb、207Pb/204Pb、208Pb/204Pb平均值逐渐降低,δ18O值和δ13C值等逐渐增高。地质和同位素地球化学特征反映水竹岭铜-铁-金-硫矿床为海底热水喷流沉积成因,揭示了块状硫化物矿床的二元结构性。 相似文献
11.
Gilles Serge Odin 《Comptes Rendus Geoscience》2002,334(6):409-414
Lithostratigraphy, physicochemical stratigraphy, biostratigraphy, and geochronology of the 77–70 Ma old series bracketing the Campanian–Maastrichtian boundary have been investigated by 70 experts. For the first time, direct relationships between macro- and microfossils have been established, as well as direct and indirect relationships between chemo-physical and biostratigraphical tools. A combination of criteria for selecting the boundary level, duration estimates, uncertainties on durations and on the location of biohorizons have been considered; new chronostratigraphic units are proposed. The geological site at Tercis is accepted by the Commission on Stratigraphy as the international reference for the stratigraphy of the studied interval. To cite this article: G.S. Odin, C. R. Geoscience 334 (2002) 409–414. 相似文献
12.
Inter-regional correlation of transgressions and regressions in the Cretaceous period 总被引:1,自引:0,他引:1
T. Matsumoto 《Cretaceous Research》1980,1(4):359-373
Well investigated platforms have been selected in each continent, and the history of Cretaceous transgressions and regressions there is concisely reviewed from the available evidence. The factual records have been summarized into a diagram and the timing of the events correlated between distant as well as adjoining areas.On a global scale, major transgressions were stepwise enlarged in space and time from the Neocomian, via Aptian-Albian, to the Late Cretaceous, and the post-Cretaceous regression was very remarkable. Minor cycles of transgression-regression were not always synchronous between different areas. Some of them were, however, nearly synchronous between the areas facing the same ocean.Tectono-eustasy may have been the main cause of the phenomena of transgression-regression, but certain kinds of other tectonic movements which affected even the so-called stable platforms were also responsible for the phenomena. The combined effects of various causes may have been unusual in the Cretaceous, since it was a period of global tectonic activity. The slowing down of this activity followed by readjustments may have been the cause of the global regression at the end of the Cretaceous. 相似文献
13.
The Afyon stratovolcano exhibits lamprophyric rocks, emplaced as hydrovolcanic products, aphanitic lava flows and dyke intrusions, during the final stages of volcanic activity. Most of the Afyon volcanics belong to the silica-saturated alkaline suite, as potassic trachyandesites and trachytes, while the products of the latest activity are lamproitic lamprophyres (jumillite, orendite, verite, fitztroyite) and alkaline lamprophyres (campto-sannaite, sannaite, hyalo-monchiquite, analcime–monchiquite). Afyon lamprophyres exhibit LILE and Zr enrichments, related to mantle metasomatism. 相似文献
14.
正20140751 Guo Xincheng(Geological Party,BGMRED of Xinjiang,Changji 831100,China);Zheng Yuzhuang Determination and Geological Significance of the Mesoarchean Craton in Western Kunlun Mountains,Xinjiang,China(Geological Review,ISSN0371-5736,CN11-1952/P,59(3),2013,p.401-412,8 相似文献
15.
正20141058 Chen Ling(Key Laboratory of Mathematical Geology of Sichuan Province,Chengdu University of Technology,Chengdu610059,China);Guo Ke Study of Geochemical Ore-Forming Anomaly Identification Based on the Theory of Blind Source Separation(Geosci- 相似文献
16.
正20141334 Chen Kun(Institute of Geophysics,China Earthquake Administration,Beijing100081,China);Yu Yanxiang Shakemap of Peak Ground Acceleration with Bias Correction for the Lushan,Sichuan Earthquake on April20,2013(Seismology and Geology,ISSN0253-4967,CN11-2192/P,35(3),2013,p.627-633,2 illus.,1 table,9 refs.)Key words:great earthquakes,Sichuan Province 相似文献
17.
正20141624 Cai Xiongfei(Key Laboratory of Geobiology and Environmental Geology,Ministry of Education,China University of Geosciences,Wuhan 430074,China);Yang Jie A Restudy of the Upper Sinian Zhengmuguan and Tuerkeng Formations in the Helan Mountains(Journal of Stratigraphy,ISSN0253-4959CN32-1187/P,37(3),2013,p.377-386,5 illus.,2 tables,10 refs.) 相似文献
18.
正20142263Lü Shaojun(Geological Survey of Jiangxi Province,Nanchang 330030,China)Early-Middle Permian Biostratigraphical Characteristics in Qiangduo Area,Tibet(Resources SurveyEnvironment,ISSN1671-4814,CN32-1640/N,34(4),2013,p.221-227,2illus.,2tables,22refs.)Key words:biostratigraphy,Lower Permian,Middle Permian,Tibet 相似文献
19.
正20142560Hu Hongxia(Regional Geological and Mineral Resources Survey of Jilin Province,Changchun 130022,China);Dai Lixia Application of GIS Map Projection Transformation in Geological Work(Jilin Geology,ISSN1001-2427,CN22-1099/P,32(4),2013,p.160-163,4illus.,2refs.) 相似文献
20.
正20140692 Duo Tianhui(No.402 Geological Team,Exploration of Geology and Mineral Resources of Sichuan Authority,Chengdu611730,China);Wang Yongli Computer Simulation of Neptunium Existing Forms in the Groundwater(Computing Techniques for Geophysical and Geochemical Exploration,ISSN1001-1749,CN51-1242/P,35(3), 相似文献