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91.
Jingwen Mao Guiqing Xie Chao Duan Franco Pirajno Dazio Ishiyama Yuchuan Chen 《Ore Geology Reviews》2011,43(1):294-314
The Middle–Lower Yangtze River Valley metallogenic belt (YRB), situated along the northern margin of the Yangtze craton, is characterized by porphyry–skarn–stratabound Cu–Au–Mo–Fe deposits in the areas of uplift and magnetite–apatite deposits in Cretaceous fault basins. Following detailed field investigations and a review of published data, we recognize two episodes of magmatism and mineralization in the YRB: 1) 156–137 Ma high-K calc-alkaline granitoids associated with 148–135 Ma porphyry–skarn–stratabound Cu–Au–Mo–Fe deposits and 2) 135–123 Ma shoshonitic series, associated with 134.9–122.9 Ma magnetite–apatite deposits. A-type granitoids and associated alkaline volcanic have a small age range from 126.5 to 124.8 Ma and are temporally, spatially and genetically associated with the second episode. The geodynamic history of the YRB did not experience the Paleozoic to Mesozoic lithospheric thickening that took place in the North China craton. This process is inferred to be linked to partial melting of the delaminated lower crust at high pressures, resulting in the development of C-type adakitic rocks. The petrochemical and Sr/Nd isotopic data show that both the shoshonitic series and A-type granitoids are quite different from adakites, with only some of the K-calc-alkaline granitoids having adakitic signatures. Previous ore genesis models were established based on an assumed relationship with adakites and a continuous tectono-thermal evolution from 150 to 100 Ma.All data obtained for the Middle–Lower Yangtze River region consistently show that the Tan–Lu regional strike-slip fault zone, initiated at 233 ± 6 to 225 ± 6 Ma from the collision between the North China and Yangtze cratons and was reactivated at ca. 160 Ma. The Tan–Lu fault was caused by the oblique subduction of the Izanagi plate, which along the YRB the low-angle subducted slab and the overlying crust was disrupted or broken due to the disharmonious movement of the two blocks. The high-K calc-alkaline granitoids magmas were derived from melting of the subducted slab, with some input of crustal material. These magmas were emplaced at the intersections between NE- and EW-trending faults and formed porphyry–skarn–stratabound Cu–Au–Mo–Fe deposits between 156 and 137 Ma. After 135 Ma the subducted plate changed its direction of motion to northeast, now running parallel to the Eurasian continental margin, and leading to large-scale continental extension. The shoshonitic series and subsequent A-type granitoids magmatism and the development of magnetite–apatite ores in the YRB, took place in both fault basins and NE-trending rifts between 135 and 124 Ma. 相似文献
92.
安徽铜陵狮子山铜矿田岩石的地球化学特征 总被引:1,自引:1,他引:0
安徽铜陵狮子山矿田是铜陵矿集区内储量最大的铜(金)矿田。矿田内矿床类型多样,成矿作用复杂,分布有东狮子山、西狮子山、大团山、老鸦岭、冬瓜山和花树坡等铜(金)矿床。这些矿床均围绕岩体产出,多数为隐伏矿,赋存于上石炭统-中三叠统的不同层位,在空间上具有明显的分带特征,由下向上依次为层控矽卡型、矽卡岩型和热液脉型矿床,其中以前2种类型最为重要。矿田成矿经历了海西期和燕山期2个时代,燕山期为主要成矿期。中酸性侵入岩是狮子山矿田内铜矿床成矿物质的主要来源。该矿田主要岩浆岩为石英闪长岩、辉石二长闪长岩和花岗闪长岩,均为高钾钙碱性系列,属中酸性岩石,为造山带派生的碱性和偏碱性花岗岩。岩石地球化学特征表明本区岩浆岩为幔源岩浆分异的产物,属于壳幔混染型,岩浆岩后期同化围岩使硅质流失,并且在岩浆侵入过程中与Na2O、K2O含量较高的围岩发生了同化混染作用,不同岩石之间可能有某种成因上的联系。 相似文献
93.
秦岭晚中生代花岗岩时空分布、成因演变及构造意义 总被引:34,自引:14,他引:20
秦岭晚中生代花岗岩主要发育于秦岭北部的华北地块南缘和北秦岭,南秦岭仅有零星出露。本文报道了3个晚中生代大岩体的年代学和其中2个岩体的地球化学和同位素数据,并系统收集了发表的相关资料,对秦岭晚中生代花岗岩进行了初步总结。华北地块南缘蓝田花岗岩的锆石LA-ICPMS U-Pb年龄为133±1Ma, εNd(t)=-11.8~-18.3, 锆石εHf(t)=-37.7~-5.7。 北秦岭构造带中牧护关花岗岩的锆石LA-ICPMS U-Pb年龄为 150±1Ma, εNd(t)=-7.6~-11.4, 锆石εHf(t)=-7.3~-17.4;蟒岭花岗岩的锆石SHRIMP U-Pb年龄为149±2 Ma。 依据收集到的26个锆石U-Pb和3个黑云母Ar-Ar年代学资料, 秦岭晚中生代花岗岩浆的演化可分为2个阶段:第一阶段为160~130Ma(晚侏罗世-早白垩世), 以I-型花岗岩为主, 主要发育于华北地块南缘和北秦岭,在南秦岭仅零星分布;第二阶段为120~100Ma(早白垩世中晚期), 以I-A过渡型和A-型花岗岩为主,主要分布在华北地块南缘的东部和北秦岭,出露面积比第一阶段小。第一阶段(160~130Ma)花岗岩主要形成于古老地壳物质的部分熔融,并有年轻幔源组分的参与,形成于挤压向伸展转换的构造环境。第二阶段(120~100Ma)花岗岩的形成除了古老地壳物质的部分熔融外,有更多的年轻幔源组分加入,发育于陆内伸展环境。花岗岩的同位素特征显示,从华北地块南缘到南秦岭,底基物质中年轻组分有增加的趋势,花岗岩的物源受深部地壳物质组成特征的控制。 相似文献
94.
西藏甲玛矿区角岩特征及其对深部找矿的意义 总被引:11,自引:2,他引:9
角岩是西藏甲玛铜多金属矿床近年来钻探工作大量揭露的赋矿围岩之一,其中蕴藏的钼铜资源量已达大型以上规模,不但为甲玛增加资源量提供了新的保障,而且在矽卡岩型和斑岩型之外增加了一种新的矿石类型。但角岩的研究相对薄弱,对其在深部找矿方面的研究更是空白。本文通过对甲玛角岩基本特征的研究,归纳了角岩的空间分布,分析了角岩的物质组成,结合角岩中裂隙的统计结果,推测了深部岩体的中心位置,为深部找矿提出了建议。认为甲玛矿区角岩分布广但厚度不均匀,以ZK3218钻孔最厚(达1027m),向周围逐渐减薄,到矿区西南角和西端多个钻孔中尖灭。角岩型矿体以辉钼矿和黄铜矿为主,ZK3217钻孔中矿体厚达900m,紧邻ZK3218钻孔,矿化普遍,但品位较矽卡岩低。角岩中裂隙统计表明,在ZK1616至ZK3216一带,裂隙密度达40条/米以上,向周围减少。综合角岩的岩石学、矿物学和地球化学等特征, 认为甲玛矿区为角岩提供热源的深部岩浆分布在ZK3216-ZK3217-ZK3218一带,建议布置深钻,深部可能存在矽卡岩型矿体和斑岩型矿体。 相似文献
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96.
西藏浦桑果铜铅锌多金属矿床S、Pb同位素组成及对成矿物质来源的示踪 总被引:1,自引:0,他引:1
西藏浦桑果铜铅锌多金属矿床位于南冈底斯成矿带火山岩浆弧内,矿区矽卡岩型铜铅锌矿体主要呈透镜状和似层状近东西向赋存于白垩系塔克那组第四岩性段矽卡岩化大理岩中。基于野外地质调查和成矿地质条件,对矿床主要金属硫化物闪锌矿、方铅矿、黄铜矿等的S、Pb同位素特征进行研究,并结合前人数据,综合探讨矿床的成矿物质来源。结果表明,浦桑果矿床矿石金属硫化物的δ34S值介于-24‰~10‰之间,平均值为-040‰,硫同位素频率直方图具明显的塔式分布特征,指示硫可能与岩浆作用有关,硫同位素具岩浆硫特征,主要与闪长玢岩有关。矿石硫化物中206Pb/204Pb变化于18344~18625之间,平均值为18555; 207Pb/204Pb变化于15549~15794之间,平均值为15716; 208Pb/204Pb变化于3812~3934之间,平均值为39044;矿石铅同位素组成稳定,为正常普通铅。结合铅同位素μ值特征(937~982)及铅同位素构造环境演化图投图结果,综合表明浦桑果矿床的矿石铅主要来源于上地壳物质且伴有地幔物质的混染,铅同位素具壳幔混源的特征。 相似文献
97.
Studies of Metallic and Trace Minerals of the Tiegelongnan Cu‐Au Deposit,Central Tibet,China 总被引:1,自引:0,他引:1
Electron probe micro-analysis(EPMA) and scanning electron microscopy(SEM) equipped with energy dispersive spectrometry(EDS) have been used to investigate the principal ore minerals and coexisting metallic mineral inclusions in polished thin sections from the Tiegelongnan deposit, which consists of a high-sulfidation epithermal system(HSES) and a porphyry system(PS). Molybdenite,chalcopyrite, bornite, tennantite, enargite, digenite, anilite, covellite, and tetrahedrite have been identified by EPMA. Intergrowth, cross-cutting and replacement relationships between the metallic minerals suggest that molybdenite formed first(stage 1),followed by chalcopyrite ± bornite ± hematite(stage 2),then bornite ± Cu-sulfides ± Cu-Fe-sulfoarsenides(stage 3),and lastly Cu-Fe-sulfoarsenides ±Cu-sulfides(stage 4). Pyrite is developed throughout all the stages. Droplet-like inclusions of Au-Te minerals commonly occur in tennantite but not in the other major sulfides(molybdenite, chalcopyrite and bornite),implying that tennantite is the most important Au telluride carrier. The pervasive binary equilibrium phases of calaverite and altaite constrain f_(Te2) in the range from ~-6.5 to ~-8 and f_(S2)-11.The intergrowth of bornite and chalcopyrite and the conversion from bornite to digenite suggest fluctuated and relatively low precipitation temperature conditions in the HSES relative to the PS.Contrastingly, the dominance of chalcopyrite in the PS, with minor bornite, suggests relatively high temperature conditions. These new results are important for further understanding the mineral formation processes superimposed by HSES and PS systems. 相似文献
98.
南非矿产资源非常丰富,储量巨大,是全球不包括能源在内的矿产资源范围价值最富有的国家。经研究,世界上最大的锰矿区、铬矿区,最大的黄金矿脉均位于南非,与我国形成了很强的经济互补性,因此对南非重要金属矿产进行开发投资具有重要的意义。结合本文整理的南非重要金属矿产锰、铂族、铬、金四大矿种资源禀赋、分布、产量、矿业公司及投资环境等,对南非进一步的投资方向和投资目标提出建议:对重点研究的锰、铂族、铬、金四大矿种提出了相关开发投资区域建议,而对于南非社会目前的不稳定性,建议中资企业可以参股形式参与当地的矿业投资,避免投资风险。 相似文献
99.
赣南浅变质岩岩石地球化学特征及稀土成矿潜力研究 总被引:2,自引:1,他引:1
赣南地区浅变质岩系分布广泛,且风化壳发育,查明浅变质岩的岩石学及地球化学特征对分析离子吸附型稀土矿床的成矿潜力具有重要作用,而目前关于变质岩离子吸附型稀土矿的研究资料较少。本文对区内广泛发育的新元古代—寒武纪浅变质岩进行采样,通过岩相学、岩石地球化学等方法对赣南浅变质岩进行分类研究。结果表明:赣南浅变质岩时代跨度大,从青白口系至泥盆系以及少量侏罗系均有出露,以新元古代面积最广,主要类型有变砂岩类、变质凝灰岩类、板岩类、千枚岩类及片岩类。其中,变砂岩类和变质凝灰岩类的稀土含量高(∑REEs平均值分别为302μg/g和246μg/g),LREEs/HREEs=2.68~5.43,目前查明的稀土矿物主要为独居石和磷钇矿。区内变质凝灰岩类产出厚度较大,稀土含量较高,风化壳发育,是良好的离子吸附型稀土矿的成矿母岩类型。千枚岩类和片岩类的平均稀土含量(∑REEs224μg/g)次之,但由于岩石风化难度较大,形成稀土风化壳型矿体可能性偏低。本研究是对变质岩离子吸附型稀土矿成矿的初步探讨,旨在为今后进一步的研究和找矿工作提供基础资料和依据。 相似文献
100.
通过搜集显生宙以来不同地质时期内海相碳酸盐岩鲕粒及胶结物矿物成分、钾盐矿床矿物种类及组合特征、蒸发岩盆地中石盐流体包裹体成分,并利用这些资料与人工海水模拟实验得到的石盐中Br分配特征的对比,得出海水成分在5.5亿年以来的显生宙期间,经历了五个阶段:其中晚元古代至寒武纪早期、二叠纪早期至中生代早期、新生代早期至现今,这些时期的原始海水组成特征系数m(SO_4~(2-))+m(HCO_3~-)/2m(Ca~(2+)),为Na-Mg-K-SO_4-Cl型海水,此期间沉积的钾盐矿床的钾镁盐矿物主要为钾盐镁矾、无水钾镁矾、杂卤石、硫酸镁石等含MgSO_4矿物,海相鲕粒和碳酸盐胶结物矿物成分为文石;而寒武纪早期至石炭纪、中生代早期至新生代早期,原始海水组成特征系数m(Ca~(2+))m(SO_4~(2-))+m(HCO_3~-)/2,为Na-Mg-KCa-Cl型海水,此期间沉积的钾镁盐矿物主要为光卤石和钾石盐,甚至含有溢晶石,海相鲕粒和碳酸盐胶结物矿物成分为方解石。根据石盐流体包裹体成分计算得出:显生宙期间,海水K+含量大部分时间变化幅度较小,为9.3~11.5mmol/kg H_2O(除了石炭纪和晚元古代),平均为10.55mmol/kg H_2O。Mg~(2+)含量在早寒武世≥67mmol/kg H_2O、晚志留世至中泥盆世31~41mmol/kg H_2O、晚古生代≥48mmol/kg H22O、晚白垩世34mmol/kg H_2O和现代55.1mmol/kg H_2O。Ca~+含量在晚元古代至古生代早期≤11mmol/kg H_2O、古生代早期至石炭纪22~35mmol/kg H_2O、石炭纪至中生代早期≤17mmol/kg H_2O、中生代早期至新生代早期19~39mmol/kg H_2O及新生代早期至今7~21mmol/kg H_2O。SO_4~(2-)含量在晚元古代至古生代早期≥23mmol/kg H_2O、古生代早期至石炭纪5~17mmol/kg H_2O、石炭纪至中生代早期13~22mmol/kg H_2O、中生代早期至新生代早期5~19mmol/kg H_2O及新生代早期至今12~29.2mmol/kg H_2O。海水Ca~(2+)与SO_4~(2-)含量的相对变化是控制海相钾盐矿床钾镁盐矿物类型的基本因素。同时,利用以上数据计算得到的显生宙各时期海水[m(Mg~(2+))+m(SO_4~(2-))]/[m(K~+)+m(Ca~(2+))]的变化与各时期海相蒸发岩系石盐层底部的Br含量变化具有同步性,进一步验证了显生宙期间海水成分是不断变化的,是约束海相蒸发岩钾盐矿物类型的主要因素。海水成分变化的控制因素为洋中脊热液和陆地水,其中洋中脊热液起主要作用,而控制这些因素变化的根本原因为板块构造运动。 相似文献