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粤北大宝山斑岩钼钨矿床赋矿岩体锆石LA-ICP-MS U-Pb年龄与矿床形成动力学背景分析 总被引:4,自引:0,他引:4
粤北大宝山斑岩钼钨矿床赋矿岩体出露面积0.18km2,矿化主要以细脉状及浸染状产于斑岩及其内外接触带中。系统的薄片观察表明,该岩体岩性比较复杂,有碱长花岗斑岩、普通花岗斑岩、白云母二长花岗斑岩及白云母花岗闪长斑岩。本文分析了碱长花岗斑岩及白云母二长花岗斑岩锆石LA-ICP-MSU-Pb年龄,碱长花岗斑岩锆石年龄为166.6±2.1Ma,MSWD=1.17;白云母二长花岗斑岩锆石年龄为166.2±3.1Ma,MSWD=2.3。两个样品的锆石U-Pb年龄基本一致,表明大宝山斑岩钼钨矿床岩体形成于燕山早期。据斑岩矿床年龄、斑岩矿床在十杭带时空分布特征及华南地区中生代构造背景,提出大宝山斑岩钼钨矿床岩体的形成可能与侏罗纪太平洋洋壳向南西俯冲而引发的的十杭带深断裂构造活动复活有关。 相似文献
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蒙古国查干苏布尔加大型铜-钼矿床地质特征及成因 总被引:10,自引:2,他引:8
查干苏布尔加斑岩铜钼矿床位于西伯利亚板块南缘近东西向和北东向深大断裂所夹持的南蒙古构造岩浆带内, 容矿围岩二长花岗斑岩与花岗闪长斑岩主量元素高SiO2(64.69?10?2~73.42?10?2), 高Al2O3 (15.33?10?2~18.35?10?2), 贫MgO(0.13?10?2~0.56?10?2), 微量元素Sr二长花岗斑岩略低(144?10?6~175?10?6), 花岗闪长斑岩表现为高Sr(样品>300?10?6, 476?10?6~720?10?6), 二者均低Y(Y<18?10?6, 2.21?10?6~ 10.20?10?6), 低Yb(Yb<1.9?10?6, 0.30?10?6~1.48?10?6), 高Sr/Y(Sr/Y>20, 21.8~63.52), 稀土元素特征为亏损重稀土, 无明显负铕异常, (87Sr/86Sr)i=0.70154~0.70397, (143Nd/144Nd)i=0.512290~0.512600,εNd(t)为+2.4~+8.5, 二长花岗斑岩和花岗闪长斑岩均具有埃达克质岩特征, 但二长花岗斑岩与花岗闪长斑岩主、微量和稀土元素又存在一定差别, 它们可能是岩浆不同演化阶段的产物。通过年龄测定, 获得辉钼矿Re-Os等时线年龄为(370.0±5.9)Ma, 二长花岗斑岩锆石SHRIMP U-Pb加权平均年龄为(365.7±3.6)Ma, 铜钼矿形成时代与二长花岗斑岩形成时代相近, 均形成于晚泥盆世。铜钼矿床与二长花岗斑岩、花岗闪长斑岩紧密共生, 矿区范围内二长花岗斑岩与花岗闪长斑岩多被蚀变并矿化, 表明二长花岗斑岩、花岗闪长斑岩与铜钼矿化存在密切的时空关系, 为铜钼成矿提供了主要成矿物质和流体来源。 相似文献
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西藏邦铺钼铜矿区花岗斑岩成岩年龄研究 总被引:1,自引:0,他引:1
邦铺钼铜矿床是发育于冈底斯成矿带的大型斑岩型钼铜矿床,矿区内岩浆岩发育,(二长)花岗斑岩为成矿母岩。利用斑岩中锆石离子探针U-Pb法和全岩Rb-Sr法测定邦铺含矿斑岩的年龄,以确定含矿斑岩的形成时代。花岗斑岩中锆石SHRIMP U-Pb法测定其年龄为14.2 Ma±0.2 Ma(MSWD=0.79);二长花岗斑岩中锆石SHRIMP U-Pb法测试值为13.9 Ma±0.3 Ma(MSWD=3.05);全岩Rb-Sr等时线年龄为13.88 Ma±0.38 Ma(MSWD=1.7)。因此14.2 Ma~3.9 Ma年龄值可以作为邦铺矿区含矿斑岩体的结晶年龄。 相似文献
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福建紫金山矿田罗卜岭铜钼矿化斑岩锆石LA-ICP- MS U-Pb年龄及成矿岩浆高氧化特征研究 总被引:11,自引:6,他引:5
罗卜岭斑岩铜钼矿床是紫金山Cu-Au-Mo浅成低温-斑岩矿田内新近发现的大型斑岩铜钼矿床,本文在岩芯及光薄片系统观察的基础上,分析了矿化斑岩锆石LA-ICP-MS U-Pb年龄及锆石Ce4/Ce3+比值.罗卜岭赋矿斑岩体可分为两期,早期为角闪黑云母花岗闪长斑岩及黑云母花岗闪长斑岩,晚期为黑云母花岗闪长斑岩.早期角闪黑云母花岗闪长斑岩和黑云母花岗闪长斑岩锆石LA-ICP-MS U-Pb年龄分别为103.7±1.2Ma,MSWD=0.33和103.0±0.9Ma,MSWD=1.00;晚期黑云母花岗闪长斑岩锆石LA-ICP-MS U-Pb年龄为97.6±2.1Ma,MSWD=6.00.罗卜岭成矿斑岩基质普遍发育硬石膏,两期成矿斑岩锆石都具较高的Ce4 +/Ce3平均值,在630 ~770之间,高于区内非成矿花岗岩锆石的Ce4+/Ce3+平均值(182 ~577),显示罗卜岭斑岩矿床成矿岩浆具有高氧逸度的特征.据罗卜岭斑岩矿床的形成时代、高氧逸度岩浆特征,结合华南地区中生代构造背景,我们初步认为罗卜岭斑岩矿床的形成可能和中生代古太平洋向北西西方向俯冲有关. 相似文献
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黑龙江鹿鸣钼矿区花岗质杂岩锆石U-Pb年龄、Hf同位素、辉钼矿Re-Os年龄及其地质意义 总被引:5,自引:2,他引:3
鹿鸣超大型钼矿(钼金属量89万吨,平均品位0.084%)产于小兴安岭-张广才岭成矿带北段,矿体呈细脉浸染状赋存于二长花岗斑岩和二长花岗岩体内,围岩蚀变有钾化、绢云母化、硅化、绿泥石化、碳酸盐化等,矿化类型主要为斑岩型矿化。鹿鸣矿区含矿岩体二长花岗斑岩和二长花岗岩的锆石U-Pb定年、Hf同位素及辉钼矿Re-Os同位素定年研究表明:二长花岗岩和二长花岗斑岩锆石的U-Pb年龄分别为186.8±2.1Ma和183.2±1.9Ma,形成于燕山早期,二长花岗斑岩晚于二长花岗岩。6个样品辉钼矿Re-Os等时线年龄为176.7±4.4Ma(MSWD=0.92),Re含量变化于30×10-6~49×10-6。二长花岗岩的锆石εHf(t)值变化于1.1~3.8,Hf单阶段模式年龄为729Ma,两阶段模式年龄为1055Ma;二长花岗斑岩的锆石εHf(t)值变化于0.4~5.9,Hf单阶段模式年龄为741Ma,两阶段模式年龄为1075Ma。研究表明成矿与二长花岗斑岩有关,并且二长花岗岩和二长花岗斑岩岩浆为中新元古代新生的地壳物质熔融的产物,成岩成矿作用与古太平洋板块俯冲作用(或佳木斯与松嫩地块的拼合)有关。 相似文献
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黑龙江多宝山斑岩Cu-Mo矿床成岩成矿时代研究 总被引:12,自引:4,他引:8
多宝山斑岩型铜(钼)矿床是中国东北地区重要的斑岩型铜(钼)矿床,文章对矿区主要成矿岩体及辉钼矿样品进行了系统的成岩成矿年代学研究。对成矿岩体采用高精度LA-ICP-MS锆石U-Pb测年,获得成矿母岩花岗闪长斑岩的锆石U-Pb年龄为(474.8±4.7) Ma,矿体寄主岩石花岗闪长岩的锆石U-Pb年龄为(478.1±4.1) Ma,以及矿体外围黑云母花岗闪长岩的锆石U-Pb年龄为(483.9±4.5) Ma;矿体辉钼矿的Re-Os同位素模式年龄加权平均值为(475.1±5.1) Ma。测年结果显示,多宝山斑岩铜(钼)矿床形成于早奥陶世。结合含矿地层、矿区岩石组合特征,以及前人研究的岩石地球化学特征,推测多宝山矿床形成于早奥陶世与板块俯冲有关的岛弧环境,说明在区域上寻找类似多宝山的斑岩铜矿应沿早奥陶世多宝山-伊尔斯岩浆岛弧带开展。 相似文献
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粤西圆珠顶斑岩型铜钼矿床成矿地质特征成岩成矿作用年代学研究 总被引:2,自引:0,他引:2
园珠顶大型铜钼矿床位于大瑶山隆起北缘、粤桂交界的广东省封开县境内。铜钼矿化普遍发育于斑岩体及其外接触带中,岩体内部见星点状黄铁矿、黄铜矿、辉钼矿分布,但铜钼工业矿体主要产于岩体外接触带中,并围绕着岩体具椭圆形环状矿化分带特征,由内向外依次为钼矿化带→铜钼矿化带→铜矿化带,成矿作用与二长花岗斑岩有关。运用高分辨率和高灵敏度离子探针和Re-Os分析技术,作者分别对矿区二长花岗斑岩和矿体进行了年代学研究,获得二长花岗斑岩的锆石U-Pb SHRIMP年龄为154±2Ma(95%可信度,MSWD=0.75,N=11),铜钼矿体辉钼矿Re-Os等时线年龄为155±5Ma(95%可信度,MSWD=0.31,N=8),表明圆珠顶斑岩型铜钼区的成岩成矿作用都发生于中侏罗世晚期,成矿作用发生于华南拉张大地构造背景下。 相似文献
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藏东玉龙斑岩铜矿带扎拉尕含矿斑岩体锆石U-Pb年龄及其地质意义 总被引:1,自引:0,他引:1
玉龙斑岩铜矿带扎拉尕斑岩铜钼矿床位于玉龙斑岩铜矿带中北部,赋矿岩体侵入下二叠统火山岩及三叠系砂泥岩中,主要由早阶段为二长花岗斑岩及晚阶段正长花岗斑岩组成。分析了早阶段二长花岗斑岩及晚阶段正长花岗斑岩锆石 LA-ICP-MS U-Pb 年龄。早阶段二长花岗斑岩该年龄为(38.5±0.2) Ma, MSWD=1.12,晚阶段正长花岗斑岩该年龄为(38.5±0.2) Ma, MSWD=1.08,早阶段和晚阶段含矿斑岩体锆石U-Pb 年龄完全一致。这表明早晚两阶段成矿岩体是在很短的时间间隔内形成的。扎拉尕赋矿斑岩体形成年龄为(38.5±0.2) Ma。据扎拉尕斑岩矿床形成时代及藏东地区在始新世至渐新世地质构造背景,提出扎拉尕斑岩矿床和玉龙斑岩铜矿带的形成与印度板块-欧亚板块碰撞在藏东地区形成的走滑构造活动诱发的岩浆活动有关,为陆陆碰撞走滑构造环境的斑岩矿床。 相似文献
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西藏岗讲斑岩铜钼矿床位于冈底斯斑岩铜矿带尼木斑岩铜矿田中。该区中-酸性岩浆活动较为发育,形成以黑云母二长花岗斑岩为主的含矿斑岩体。为限定冈底斯斑岩铜矿带岗讲铜钼矿床含矿斑岩体的形成时代及成因背景,本次研究对成矿黑云母二长花岗斑岩进行了LA-ICP-MS锆石U-Pb定年和地球化学研究。锆石U-Pb年代学分析揭示,岗讲黑云母二长花岗斑岩形成于中新世(14.47±0.19 Ma)。岩石地球化学研究表明,岗讲黑云母二长花岗斑岩的w(SiO2)为69.12%~72.62%,w(Al2O3)为13.31%~15.57%、K2O/Na2O为0.76~1.66。属于钾玄岩系列-高钾钙碱性系列,为过铝质花岗岩。岩石的ΣREE为83.19×10-6~154.28×10-6,轻、重稀土分异明显,(LREE/HREE)=3.57~14.73,(La/Yb)N值为31.4~39.5,δEu为0.83~1.29,具有较弱的负Eu异常;稀土元... 相似文献
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西藏甲玛超大型铜矿区斑岩脉成岩时代及其与成矿的关系 总被引:7,自引:3,他引:4
甲玛铜多金属矿是冈底斯成矿带上资源储量达到超大型规模的又一个重要矿床,2010年7月已正式投产。产于矽卡岩、斑岩和角岩中的辉钼矿Re-Os定年已表明甲玛矿床的铜钼成矿时代集中于17~14Ma,而成岩时代的研究相对较少,尤其是矿区及外围大量出露的近南北向展布的斑岩脉。本文选取矿区铅山上52号平硐内的2件弱矿化斑岩脉样品,花岗斑岩(JM52-0)和花岗闪长斑岩(JM52-46.7),首次开展斑岩脉的锆石SHRIMP U-Pb定年,获得的206Pb/238U-207Pb/235U协和年龄分别为14.2±0.2Ma和14.1±0.3Ma,代表了甲玛矿区地表出露的近南北向展布的斑岩脉侵位时岩浆锆石的结晶年龄。斑岩脉的成岩时代与区域上与近南北向正断层系统及裂谷裂陷带有关的冈底斯含矿斑岩侵位时代(18~12Ma)一致。甲玛的成岩成矿时代显示了成岩作用与成矿作用基本同期,且与冈底斯成矿带东段主要斑岩型-矽卡岩型铜多金属矿床的成岩成矿时代基本一致,成矿高峰集中在17~14Ma之间,指示了冈底斯在中新世的岩浆构造活动事件,而且表明了甲玛铜钼矿化与岩浆热液的成因联系。 相似文献
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西藏冈底斯成矿带的斑岩-矽卡岩成矿系统:--来自斑岩矿床和矽卡岩型铜多金属矿床的Re-Os同位素年龄证据 总被引:15,自引:4,他引:11
笔者通过对冈底斯成矿带驱龙、厅宫斑岩铜矿区和甲马、知不拉等矽卡岩型铜多金属矿区的辉钼矿样品进行的Re-0s法同位素定年研究,获得驱龙、厅宫、甲马和知不拉等矿区的精确成矿年龄。4件驱龙斑岩铜矿区辉钼矿样品的Re-Os模式年龄介于(15.75±0.42)Ma~(16.23±0.90)Ma之间,等时线年龄为(15.99±0.32)Ma;7件厅宫斑岩铜矿矿区辉钼矿样品的Re-Os模式年龄介于(15.5±0.3)Ma~(16.3±0.3)Ma之间,等时线年龄为(15.49±0.36)Ma;在矽卡岩型铜多金属矿区中,7件甲马矿区辉钼矿样品的Re-Os模式年龄介于(15.4±0.2)Ma~(15.5±0.2)Ma之间,等时线年龄为(15.18±0.98)Ma;5件知不拉矿区辉钼矿样品的Re-Os模式年龄介于(16.88±0.28)Ma~(17.06±0.27)Ma之间,等时线年龄为(16.90±0.64)Ma。斑岩铜矿区和矽卡岩型铜多金属矿区所获得的年龄数据基本一致,其年龄明显晚于中生代弧间盆地和碰撞型花岗岩的发育时间,同时矽卡岩型铜多金属矿床在空间上亦分布于斑岩铜矿床的外围。因此笔者认为甲马和知不拉等铜铅锌矿床与冈底斯成矿带新生代晚期大规模成矿形成的斑岩铜钼矿床属于统一的斑岩-矽卡岩成矿系统,是由深源花岗质岩浆的岩浆-热液系统在不同的围岩介质条件成矿的产物。 相似文献
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WANG Liqiang CHEN Yuchuan TANG Juxing Lü Pengrui LUO Maocheng WANG Huan CHEN Wei LENG Qiufeng 《《地质学报》英文版》2012,86(5):1225-1240
The multi-stage intrusions of intermediate-acid magma occur in the Bangpu mining district, the petrogenic ages of which have been identified. The times and sequences of their emplacement have been collated and stipulated in detail in this paper by using the laser ablation-inductively coupled plasma-mass spectrometry (LA-ICP-MS) zircon U-Pb dating method. The ages of biotite monzogranite that were formed before mineralization in the southwest of this mining district are 70±1?Ma (mean square of weighted deviates (MSWD) =9.5, n=8) and 60.60±0.31?Ma (MSWD=3.8, n=16), which belong to the late Cretaceous–early Paleocene in age. That means, they are products of an early tectonic-magmatic event of the collision between the Indian and Asian continentals. The ages of ore-bearing monzogranite porphyry and ore-bearing diorite porphyrite are 16.23±0.19?Ma (MSWD=2.0, n=26) and 15.16±0.09?Ma (MSWD=3.9, n=5) separately, which belong to the middle Miocene in age; namely, they are products of the Gangdese post-collision extensional stage when crust-mantle materials melted and mixed as well as magmatic intrusion simultaneously occurred. Some zircons with ages of 203.6±2.2?Ma (MSWD=1.18, n=7) were captured in the ore-bearing diorite porphyrite, which shows that there had been tectono-magmatic events in the late Triassic–early Jurassic. Molybdenum (copper) ore-bodies produced in the monzogranite porphyry and copper (molybdenum) ore-bodies produced in the diorite porphyrite are the main ore types in this ore deposit. The model ages of Re-Os isotopic dating for the 11 molybdenite are 13.97–15.84?Ma, while isochron ages are 14.09±0.49?Ma (MSWD=26). The isochron ages of seven molybdenite from molybdenum (copper) ore with monzogranite porphyry type are 14.11±0.31?Ma (MSWD=5.2). There is great error in the isochron ages of four molybdenite from copper (molybdenum) ore with diorite porphyrite type, and their weighted average model ages of 14.6±1.2?Ma (MSWD=41), which generally represent the mineralization age. The results about the Re-Os isotopic dating of molybdenite in the ore of different types have limited exactly that, the minerlazation age of this ore deposits is about 14.09?Ma, which belongs to the middle Miocene mineralization. The Bangpu deposit has a uniform metallogenic dynamics background with the porphyry type and skarn-type deposits such as Jiama, Qulong and others. 相似文献
15.
冈底斯成矿带东段矿床成矿系列及找矿突破的关键问题研究 总被引:15,自引:0,他引:15
冈底斯成矿带是我国最重要的资源接续基地之一,其中冈底斯岩浆弧(III43)是最重要的Ⅲ级成矿带,研究程度最高在拉孜县-工布江达县长约600km、宽约90km范围内,已发现并评价了5个超大型矿集区:雄村铜金矿集区,厅宫-冲江铜多金属矿集区,甲玛-驱龙-邦铺铜多金属矿矿集区,蒙亚啊-洞中拉-亚贵拉多金属矿集区,程巴-努日钨钼铜矿集区。根据近年来的研究成果,厘定出与海西期火山作用、海西期裂谷构造有关的铅锌银矿床成矿系列组、印支-燕山期与沉积-构造岩浆作用有关的铜、金、铁、铅锌、银、钼矿床成矿系列组以及冈底斯成矿带内喜山期与构造岩浆、沉积作用有关的铜、金、铁、铅锌、银、钼、钨、铀、盐类矿床成矿系列组,包括6个矿床成矿系列和10个成矿亚系列。主要的矿床成矿亚系列为:与早侏罗世-晚侏罗世岛弧型中酸性火山岩-浅成岩建造有关的铜、金、银、铅锌矿床成矿亚系列,成矿年龄173~160Ma,雄村外围和拉萨以东广泛分布的叶巴组分布区是其主要找矿远景区;与古新世-始新世中酸性火山-中浅成岩浆建造有关的铅锌、银、钼、钨、铁矿床成矿亚系列(沙让式、亚贵拉式、洞中拉式),成矿年龄在65~38Ma,林周盆地-南木林盆地及其北侧的隆格尔断隆带是主要的找矿远景区;与中新世中酸性浅成岩浆建造有关的铜、钼、铅锌、钨、金、银矿床成矿亚系列(驱龙式、甲玛式、冲江-厅宫式、朱诺式、邦铺式),成矿年龄17~13Ma,冈底斯成矿带东段中带是主要的找矿远景区,尤其是含矿斑岩体接触带的矽卡岩型铜多金属矿,如新发现的普桑果矽卡岩型铜铅锌矿。成矿元素从南往北的分布规律为Cu-Au(斑岩型)→Mo-W(Cu)(斑岩-矽卡岩型)→Cu-Mo-Pb-Zn(Au、Ag)(斑岩-矽卡岩型)→Mo(Cu)(斑岩)→Pb-Zn-Mo-W-Fe(斑岩-矽卡岩型)→Pb、Zn(Ag)(热液脉型)。成矿时代从南往北的规律为173~154Ma(雄村)→40~20Ma(努日-程巴等)→17~13Ma(驱龙、甲玛等)→65~38Ma(沙让、亚贵拉等)。冈底斯成矿带强烈的燕山晚期、喜山期的黑云母花岗岩(花岗斑岩、石英斑岩)岩浆活动控制了矽卡岩型铜铅锌铁钼矿床的分布,形成岩体中Cu、Mo、W矿化,外围接触带(0~4km)灰岩与黑色岩系的层间构造中的Mo-W-Cu-Zn-Pb-Ag-Au矿化分带,主要的含矿岩系组合是灰岩(大理岩)+黑色板岩、凝灰岩、砂板岩。主要的含矿层位为晚石炭-早二叠世昂杰组、来姑组,二叠纪的洛巴堆组、下拉组,中侏罗世多底沟组与晚侏罗世林布宗组层间构造。按照"缺位"理论预测燕山晚期-喜山早期(126~40Ma)念青唐古拉地区矽卡岩型多金属矿附近的斑岩钼(铜)矿等5种主要矿床类型和雄村铜金矿外围,拉萨以东叶巴组(J2y)大面积分布地区等4个主要预测区,提出了增生楔中的造山型金矿的找矿突破、推覆-滑覆构造控岩控矿模型的构建等当前找矿突破中的关键地质问题。 相似文献
16.
Bangpu deposit in Tibet is a large but poorly studied Mo-rich (~ 0.089 wt.%), and Cu-poor (~ 0.32 wt.%) porphyry deposit that formed in a post-collisional tectonic setting. The deposit is located in the Gangdese porphyry copper belt (GPCB), and formed at the same time (~ 15.32 Ma) as other deposits within the belt (12 ~ 18 Ma), although it is located further to the north and has a different ore assemblage (Mo–Pb–Zn–Cu) compared to other porphyry deposits (Cu–Mo) in this belt. Two distinct mineralization events have been identified in the Bangpu deposit which are porphyry Mo–(Cu) and skarn Pb–Zn mineralization. Porphyry Mo–(Cu) mineralization in the deposit is generally associated with a mid-Miocene porphyritic monzogranite rock, whereas skarn Pb–Zn mineralization is hosted by lower Permian limestone–clastic sequences. Coprecipitated pyrite and sphalerite from the Bangpu skarn yield a Rb–Sr isochron age of 13.9 ± 0.9 Ma. In addition, the account of garnet decreases and the account of both calcite and other carbonate minerals increases with distance from the porphyritic monzogranite, suggesting that the two distinct phases of mineralization in this deposit are part of the same metallogenic event.Four main magmatic units are associated with the Bangpu deposit, namely a Paleogene biotite monzogranite, and Miocene porphyritic monzogranite, diabase, and fine-grained diorite units. These units have zircon U–Pb ages of 62.24 ± 0.32, 14.63 ± 0.25, 14.46 ± 0.38, and 13.24 ± 0.04 Ma, respectively. Zircons from porphyritic monzogranite yield εHf(t) values of 2.2–8.7, with an average of 5.4, whereas the associated diabase has a similar εHf(t) value averaging at 4.7. The geochemistry of the Miocene intrusions at Bangpu suggests that they were derived from different sources. The porphyritic monzogranite has relatively higher heavy rare earth element (HREE) concentrations than do other ore-bearing porphyries in the GPCB and plots closer to the amphibolite lithofacies field in Y–Zr/Sm and Y–Sm/Yb diagrams. The Bangpu diabase contains high contents of MgO (> 7.92 wt.%), FeOt (> 8.03 wt.%) but low K2O (< 0.22 wt.%) contents and with little fractionation of the rare earth elements (REEs), yielding shallow slopes on chondrite-normalized variation diagrams. These data indicate that the mineralized porphyritic monzogranite was generated by partial melting of a thickened ancient lower crust with some mantle components, whereas the diabase intrusion was directly derived from melting of upwelling asthenospheric mantle. An ancient lower crustal source for ore-forming porphyritic monzogranite explains why the Bangpu deposit is Mo-rich and Cu-poor rather than the Cu–Mo association in other porphyry deposits in the GPCB because Mo is dominantly from the ancient crust.The Bangpu deposit has alteration zonation, ranging from an inner zone of biotite alteration through silicified and phyllic alteration zones to an outer propylitic alteration zone, similar to typical porphyry deposits. Some distinct differences are also present, for example, K-feldspar alteration at Bangpu is so dispersed that a distinct zone of K-feldspar alteration has not been identified. Hypogene mineralization at Bangpu is characterized by the early-stage precipitation of chalcopyrite during biotite alteration and the late-stage deposition of molybdenite during silicification. Fluid inclusion microthermometry indicates a change in ore-forming fluids from high-temperature (320 °C–550 °C) and high-salinity (17 wt.%–67.2 wt.%) fluids to low-temperature (213 °C–450 °C) and low-salinity (7.3 wt.%–11.6 wt.%) fluids. The deposit has lower δDV-SMOW (− 107.1‰ to − 185.8‰) values compared with other porphyry deposits in the GPCB, suggesting that the Bangpu deposit formed in a shallower setting and is associated with a more open system than is the case for other deposits in this belt. Sulfides at Bangpu yield δ34SV-CDT values of − 2.3‰ to 0.3‰, indicative of mantle-derived S implying that coeval mantle-derived mafic magma (e.g., diabase) simultaneously supplied S and Cu to the porphyry system at Bangpu. In comparison, the Pb isotopic compositions (206Pb/204Pb = 18.79–19.28, 207Pb/204Pb = 15.64–15.93, 208Pb/204Pb = 39.16–40.45) of sulfides show that other metals (e.g., Mo, Pb, Zn) were likely derived mainly from an ancient crustal source. Therefore, the formation of the Bangpu deposit can be explained by a two-stage model involving (1) the partial melting of an ancient lower crust triggered by invasion of asthenospheric mantle-derived mafic melts that provide heat and metal Cu and (2) the formation of the Bangpu porphyry Mo–Cu system, formed by magmatic differentiation in the overriding crust in a post-collisional setting. 相似文献
17.
十二排钼矿床位于上杭-云霄断裂带与闽西南拗陷的复合部位,是紫金山铜金矿田外围新近探明的一处具有中大型远景的斑岩型钼矿床。野外地质调查显示,其钼矿化呈细脉状、网脉状主要产出于黑云母二长花岗岩和黑云母花岗斑岩中。热液蚀变具有斑岩型矿床的分带特征,由黑云母花岗斑岩向外依次发育钾硅酸盐化带、绢英岩化带和青磐岩化带,钼矿体主要赋存于绢英岩化与钾硅酸盐化构成的叠加带中。锆石U-Pb定年结果表明,黑云母二长花岗岩和黑云母花岗斑岩分别形成于(143.1±0.9)Ma和(143.5±0.4)Ma。4件辉钼矿样品的Re-Os加权平均年龄为(143.9±2.1)Ma。辉钼矿的w(Re)为1.2×10~(-6)~7.8×10~(-6),说明成矿物质可能主要来自地壳。岩石地球化学分析结果显示,十二排含矿花岗岩具有相似的主量和微量元素组成,均属于弱过铝质高钾钙碱性I型花岗岩,其中,黑云母花岗斑岩表现出高分异花岗岩特征,两者可能是古老变质基底来源的熔体经历不同程度分异结晶的产物,并混入有少量幔源物质。综合已有的资料,文章认为十二排斑岩型钼矿化与早白垩世早期花岗质岩浆活动密切相关,上杭-云霄断裂带存在古太平洋板块俯冲后撤引发构造体制转换阶段的成岩成矿响应,进一步找矿勘查工作应加强评价早白垩世早期高分异花岗岩体的钼多金属成矿潜力。 相似文献
18.
陕西省镇安县桂林沟斑岩型钼矿床位于南秦岭多金属成矿带内,其成矿围岩主要为细粒花岗岩、钾长花岗岩和蚀变的粗粒花岗岩。本文通过对桂林沟斑岩型钼矿床中辉钼矿Re-Os同位素定年以及围岩中锆石U-Pb年代学研究,旨在探讨成矿成岩的关系及其构造意义。结果表明,6件辉钼矿的Re-Os同位素年龄在195.9~198.5Ma之间,加权平均年龄为197.2±1.3Ma,表明桂林沟钼矿形成于早侏罗世。围岩细粒花岗岩、钾长花岗岩和粗粒花岗岩的锆石U-Pb年龄分别为199±1.4Ma、201±3.1Ma和198±11Ma,这说明其成岩和成矿年龄基本一致。值得注意的的是,桂林沟钼矿床的形成年龄不同于前人已报导的秦岭钼矿的三个主要成矿期,即238~213Ma、145~126Ma和116~110Ma,其稍晚于第一成矿期。200~190Ma可能代表了秦岭成矿带一期尚未认识的重要成矿事件,对于南秦岭找矿具有重要意义。该期钼矿形成于秦岭印支期碰撞之后,是在造山带垮塌引起的岩浆-热液事件过程中形成的。 相似文献
19.
西藏甲玛铜多金属矿床矽卡岩中辉钼矿铼-锇同位素定年及其成矿意义 总被引:36,自引:1,他引:35
西藏甲玛铜多金属矿床中辉钼矿是主要的矿石矿物,普遍发育,产出于不同的矿石类型(角岩型、矽卡岩型、斑岩型)矿石中。辉钼矿大多分布于裂隙、节理面上和石英脉或不同岩性岩石中。矽卡岩型矿石中辉钼矿呈微细粒浸染状、团斑状、脉状等,直接分布于矽卡岩中或矽卡岩中后期的石英脉中。采集西藏甲玛铜多金属矿床矽卡岩型矿石中不同产状的辉钼矿,进行铼-锇同位素测年,得到等时线年龄为(15.34±0.10)Ma,模式年龄变化于(15.21±0.22)Ma~(15.50±0.22)Ma,说明甲玛的辉钼矿成矿年龄集中在15Ma左右。结合前人的年代学研究成果,认为甲玛铜多金属矿成矿时代与冈底斯斑岩铜矿带斑岩铜矿的成矿年龄相近,可以否定甲玛铜多金属矿海底喷流沉积成矿成因的观点,为甲玛铜多金属矿的成矿成因和斑岩-矽卡岩型矿体的深部找矿提供了理论依据。 相似文献
20.
江西九瑞地区宝山斑岩型铜多金属矿床锆石U-Pb和辉钼矿Re-Os年龄及其地质意义 总被引:6,自引:2,他引:4
宝山斑岩型铜多金属矿床位于九瑞矿集区西北部,隶属于九江-瑞昌铜金矿田,为长江中下游铜金成矿带、大冶-九江成矿亚带的组成部分。对宝山岩体的花岗闪长斑岩进行LA-MC-ICP-MS U-Pb同位素测年,获得其锆石U-Pb年龄为(147.81±0.48)Ma(MSWD=1.07);首次对宝山矿床的辉钼矿进行Re-Os同位素定年,获得矿床的成矿年龄:6件辉钼矿的Re-Os同位素模式年龄范围为(146.1±2.2)Ma~(148.7±2.0)Ma,加权平均年龄为(147.42±0.84)Ma,等时线年龄为(147.7±1.2)Ma。成岩年龄与成矿年龄在误差范围内一致。辉钼矿的Re含量指示宝山矿床的成矿物质来自于壳幔混源。宝山矿区的成岩、成矿时代与九瑞矿集区典型岩体和矿床的成岩、成矿时代相似,也与长江中下游地区铜陵、安庆和鄂东南(部分地区)的典型铜多金属矿床的成岩、成矿时代基本一致,都属于长江中下游成矿带早白垩世多金属成矿事件的一部分。 相似文献