LA-ICP-MS zircon U-Pb dating of alkali-feldspar granite on the periphery of the Oyu Tolgoi deposit, Mongolia, and its geological significan
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摘要:
位于蒙古国Oyu Tolgoi超大型斑岩型铜-金矿床南20km的碱长花岗岩区, 构造上处于西伯利亚板块南缘近东西向和北东向深大断裂所挟持的戈壁-天山古生代岛弧带内。利用LA-ICP-MS U-Pb同位素测年法对研究区碱长花岗岩中的锆石进行高精度的年代学测试, 获得206Pb/238U年龄加权平均值为286.00± 0.91Ma, 为早二叠世。研究区具有多期次成岩、成矿特征, 本次定年不仅为该区多期次岩浆活动提供了直接的年龄证据, 也为该区找矿指明了方向。
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关键词:
- 锆石 /
- 花岗岩 /
- Oyu Tolgoi /
- 蒙古
Abstract:The alkali-feldspar granite of the study area located 20km south of the superlarge Oyu Tolgoi Cu-Au deposit. The tecton-ic setting of the study area belongs to Paleozoic island arc zone of Gobi-Tianshan controlled by intersection of the near-latitudinal fault and an oblique transverse fault on the south margin of Siberian plate. A sample was collected from Onealkali-feldspar granite, and CL characteristics of zircons suggest magmatic origin. LA-ICP-MS U-Pb dating of zircon from the sample shows that the em-placing age is 286.0± 0.91Ma (MSWD=1.4), belonging to Permian period. The study area is characterized by multiperiodic diagenesis and mineralization. The isotope age provides not only the direct evidence for the multiperiodic magmatic activities but also the pros-pecting direction for the study area.
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Keywords:
- zircon /
- alkali-feldspar granite /
- Oyu Tolgoi /
- Mongolia
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近年来,加拿大Ivanhoe Mines公司在蒙古国南戈壁Turquoise Hill地区发现Oyu Tolgoi超大型斑岩型铜-金-(钼)矿床,引起矿产勘查界的高度关注。已有研究表明,该矿床铜-金矿蚀变带中黑云母K-Ar同位素年龄为411±3Ma[1],对该矿床中辉钼矿样品进行Re-Os同位素年龄测定,结果为373~370±1.2Ma[2]。Wainwright[3]报道,侵入最新层序矿化碎屑序列的石英二长闪长岩的U-Pb年龄介于378±3~369±2Ma之间,表明该矿床形成于泥盆纪,与查干苏布尔加斑岩型铜-钼矿床成矿时代一致[4]。该矿床外围岩体广泛分布,以晚古生代为主,并形成了一系列与之相关的大中型矿床:Shuteen斑岩铜-金矿床、Nariinhudag斑岩铜(±金)矿床、Hongoot斑岩铜-钼(±金、银)矿、Khan Bogol铊-铌-稀土矿床及Lugiin gol稀土(铊、铌、铁)矿床[5-8]。因此对该区外围多金属、稀有-稀土金属矿床的找寻,成为重要的找矿方向,而对与成矿关系密切的岩体时代的测定,对指导该区找矿具有重要的指示意义。蒙古地质工作程度较低,地质单元精确同位素定年更是少之又少。本文通过LA-ICP-MS锆石U-Pb测年技术,对Oyu Tolgoi外围岩体进行高精度U-Pb同位素定年,为该区的基础地质、矿产地质研究提供新的佐证,为该区找矿提供年代学依据。
1. 区域地质概况
研究区位于蒙古国Oyu Tolgoi南20km,距中国国界约60km,构造上处于南蒙古海西期构造-岩浆岩带中段、西伯利亚板块南缘近东西向和北东向深大断裂夹持的戈壁-天山古生代岛弧带内。由于该区邻近蒙古南部和南戈壁构造区的交界部位,构造-岩浆活动复杂。在古生代时,蒙古南部经历了岛弧增生和安第斯型俯冲,火山弧和大陆地块的生成与此相关。早古生代火山岩、沉积岩分布于研究区的北部,与围岩呈断层及角度不整合接触。自晚古生代以来,受到盆地和山脉隆升的影响,双峰式火山作用强烈,研究区内出现的泥盆纪及石炭纪地层均以火山-火山沉积建造为主,泥盆系岩石组合为海相安山岩-英安岩、英安流纹岩和深海相硅质岩,具有岛弧岩浆岩带典型岩石组合的特点。石炭系海相-滨海相火山-陆源沉积组合主要为安山-英安岩、英安-流纹岩及碳酸盐岩、凝灰岩、陆源碎屑岩;基性-酸性陆相火山岩和偏碱性陆相火山岩及碎屑岩岩石组合为玄武岩、玄武安山岩、安山岩、英安岩、流纹岩和玄武粗面岩、粗面岩、粗面玄武岩、粗安岩、安山-流纹-粗面流纹岩,以及砂岩、粉砂岩等,属典型的成熟岛弧带岩石组合,这种岩石系列和岩石组合暗示本区在石炭纪已经开始出现大陆碰撞和海域封闭(图 1)。
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图 1 蒙古Oyu Tolgoi外围地质简图1—志留纪火山沉积地层;2—泥盆纪火山岩地层;3—石炭纪火山岩地层;4—白垩纪陆源沉积地层;5—新生代沉积地层;6—碱长花岗岩;7—花岗岩;8—断裂;9—Oyu Tolgoi斑岩型铜-金矿床;10—采样点Figure 1. Simplified geological map of the periphery of Oyu Tolgoi, Mongolia研究区内大面积出露的花岗质岩石,主要由正长岩、花岗岩、碱长花岗岩、长石斑岩、长石角闪石斑岩、石英长石斑岩等组成,岩石普遍发生区域变质和变形作用,为多期侵位复式杂岩体。前人依据岩石的变形变质特征及其与地层的接触关系,将该区域岩体时代多定为泥盆纪和石炭纪,缺乏精确的同位素定年证据[9-12]。
2. 样品采集与测试
2.1 样品采集与处理
采集的碱长花岗岩样品MND105TW1位于Oyu Tolgoi南20km(GPS坐标:N42°49′17.2″、E106°47′26.2″),该样品岩性为中粒碱长花岗岩(图 2),岩石呈灰白色-浅肉红色,中粒花岗结构,块状构造,主要造岩矿物为石英(30%~40%)、钾长石(30%~35%)、斜长石(20%~30%)、黑云母(约5%),石英呈他形粒状结构;钾长石呈他形粒状-不规则状,少量钾长石中含有钠长石条纹;斜长石呈自形-半自形板柱状,聚片双晶发育,双晶纹细小(图 3)。蒙古地质资料中将该岩体时代定为晚泥盆世。
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图 2 蒙古Oyu Tolgoi碱长花岗岩野外照片Figure 2. Main sample photos of alkalic feldspar granite in the peripheral Oyu Tolgoi, Mongolia![]()
图 3 蒙古Oyu Tolgoi外围二长花岗岩锆石阴极发光图像Figure 3. CL images of monzogranite on the periphery of Oyu Tolgoi, Mongolia锆石挑选在河北省区域地质调查所实验室完成,采用人工破碎、重砂淘洗法从碱长花岗岩样品中分离锆石,在双目镜下挑纯,锆石纯度达99%以上,无氧化、无污染。挑选出的锆石多于1000粒,这些锆石多呈浅黄色、无色,透明度良好,金刚光泽,以长柱状、短柱状为主,半自形-自形晶。
2.2 测试方法
将挑选好的待测锆石颗粒置于环氧树脂制靶,用于阴极发光研究及锆石U-Pb测年。锆石阴极发光图像拍摄在中国地质科学院矿产资源研究所电子探针研究室完成。锆石U-Pb同位素测年在天津地质调查中心实验室利用LA-ICP-MS完成。激光剥蚀系统为GeoLas 2005,ICP-MS为Agilent7500a。激光剥蚀过程中采用氦气作为载气,氩气为补偿气以调节灵敏度,二者在进入ICP之前通过一个T型接头混合。在等离子体中心气流(氩+氦)中加入了少量氮气,以提高仪器灵敏度、降低检出限和改善分析精密度[13]。利用193nm激光器对锆石进行剥蚀,激光剥蚀束斑直径为35μm或50μm进行锆石U-Pb同位素原位测定。采用TEMORA作为外部锆石年龄标准。利用NIST612玻璃标本作为外标,计算锆石U、Th、Pb的含量。采用Isoplot程序进行数据处理。具体仪器性能、分析方法及测试过程见李怀坤等[14]。
2.3 测试结果
锆石的阴极发光(CL)图像在中国地质科学院矿产资源研究所电子探针研究室完成,根据阴极发光图像形态判断(图 3),锆石振荡环带清晰,晶体形态多呈自形柱状,绝大部分有清晰的核、幔、边结构。对其中的20颗锆石进行统计,长120~230μm,宽70~100μm,长宽比为1.71∶1~3.29∶1,应为典型的岩浆成因锆石,部分锆石边部具有明显的暗化边,表明其遭受了变质或后期的热液蚀变作用。部分锆石颗粒在透射光下可见裂纹和细小的包裹体。
锆石U-Pb同位素测试数据经普通铅校正后,分析测试结果列于表 1。锆石的有效测试点共22个,除19号数据点外,所有数据Th/U值较高,在0.32~1.53之间,具有岩浆结晶锆石的特征[15]。锆石的结晶年龄可以代表碱长花岗岩的成岩年龄,而第19个测试点Th/U值很低,为0.06,从CL图像可以看出,该锆石具有明显的增生边,锆石核部存在1颗结构不同的锆石,由此可以推断,该粒锆石后期经历了热液作用或变质作用,因此,应扣除该点的测年数据。第3点锆石206Pb/238U年龄为308Ma,为岩浆成因锆石,在其他所有锆石点数据中,只有该点年龄值偏高,可能为捕获锆石,故在谐和图中也将此点扣除。由表 1可以看出,Pb含量为8×10-6~35×10-6,U含量为122×10-6~590×10-6。由于年轻锆石中放射成因207Pb含量较少,因此,对年轻锆石均使用206Pb/238U年龄,206Pb/238U年龄加权平均值被认为是锆石的形成时间。有些锆石的普通铅含量较高且不均一,在普通铅扣除不准确时会导致测试数据点呈近平行于X轴的一条直线,而从该样品的206Pb/207Pb-238U/207Pb等时线图(图 4-a)可以看出,所有样品点均落在等时线上,表明并没有发生放射性成因Pb丢失,锆石为同一岩浆源区。在该样品207Pb/235U-206Pb/238U的谐和图中可以看出(图 4-b),所有数据点呈近平行于X轴的直线,206Pb/238U年龄加权平均值为286.00±0.91Ma(MSWD=1.4),这个年龄可被解释为研究区碱长花岗岩的侵位年龄,表明Oyu Tolgoi外围该碱长花岗岩体形成时代为早二叠世。
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图 4 蒙古Oyu Tolgoi外围碱长花岗岩LA-ICP-MS锆石U-Pb谐和图Figure 4. LA-ICP-MS zircon U-Pb concordia plots for monzogranite on the periphery of Oyu Tolgoi, Mongolia表 1 蒙古Oyu Tolgoi外围碱长花岗岩LA-ICP-MS锆石U-Th-Pb分析测试结果Table 1. LA-ICP-MS U-Th-Pb analytical data for zircons from alkalifeldspar granite on the periphery of Oyu Tolgoi, Mongolia样品号 含量/10-6 Th/U 同位素比值 年龄/Ma MND105
TW1Pb U 206Pb/238U 1σ 207Pb/235U 1σ 207Pb/206Pb 1σ 208Pb/232Th 1σ 232Th/238U 1σ 206Pb/238U 1σ 207Pb/235U 1σ 207Pb/206Pb 1σ 1 13 252 1.1015 0.0452 0.0003 0.3256 0.0050 0.0522 0.0008 0.0110 0.0000 1.1015 0.0033 285 2 286 4 294 35 2 14 273 1.0760 0.0455 0.0002 0.3267 0.0080 0.0520 0.0013 0.0100 0.0001 1.0760 0.0037 287 2 287 7 287 55 3 8 143 0.9685 0.0489 0.0003 0.5628 0.0220 0.0835 0.0033 0.0151 0.0002 0.9685 0.0008 308 2 453 18 1282 76 4 16 297 1.3339 0.0454 0.0002 0.4120 0.0052 0.0658 0.0009 0.0107 0.0000 1.3339 0.0043 286 2 350 4 801 28 5 15 261 1.5262 0.0454 0.0003 0.4954 0.0052 0.0792 0.0008 0.0109 0.0001 1.5262 0.0229 286 2 409 4 1177 19 6 35 590 1.4658 0.0454 0.0003 0.5424 0.0058 0.0866 0.0007 0.0125 0.0001 1.4658 0.0233 286 2 440 5 1351 16 7 8 155 0.9604 0.0454 0.0003 0.3134 0.0076 0.0500 0.0012 0.0100 0.0001 0.9604 0.0033 286 2 277 7 196 56 8 14 165 1.0349 0.0454 0.0003 0.7935 0.0119 0.1267 0.0018 0.0418 0.0007 1.0349 0.0185 286 2 593 9 2053 25 9 12 221 0.8357 0.0454 0.0002 0.3254 0.0062 0.0520 0.0009 0.0156 0.0003 0.8357 0.0063 286 2 286 5 285 42 10 12 229 0.9812 0.0454 0.0003 0.4411 0.0077 0.0705 0.0012 0.0114 0.0001 0.9812 0.0065 286 2 371 6 943 36 11 14 247 1.5680 0.0454 0.0003 0.6633 0.0153 0.1059 0.0027 0.0104 0.0001 1.5680 0.0079 286 2 517 12 1731 46 12 9 142 0.8280 0.0454 0.0003 0.8101 0.0245 0.1295 0.0036 0.0220 0.0003 0.8280 0.0054 286 2 603 18 2091 49 13 11 195 1.3956 0.0453 0.0003 0.6111 0.0141 0.0979 0.0022 0.0110 0.0001 1.3956 0.0059 286 2 484 11 1584 43 14 11 212 0.9225 0.0455 0.0003 0.3264 0.0052 0.0520 0.0009 0.0106 0.0001 0.9225 0.0016 287 2 287 5 286 38 15 10 197 0.9360 0.0455 0.0003 0.3268 0.0054 0.0521 0.0009 0.0105 0.0001 0.9360 0.0091 287 2 287 5 289 40 16 9 191 0.3169 0.0454 0.0003 0.4219 0.0102 0.0674 0.0016 0.0111 0.0001 0.3169 0.0008 286 2 357 9 849 48 17 10 204 0.9624 0.0452 0.0003 0.3257 0.0058 0.0523 0.0009 0.0102 0.0001 0.9624 0.0134 285 2 286 5 298 39 18 6 122 1.1580 0.0458 0.0003 0.3252 0.0091 0.0515 0.0014 0.0106 0.0001 1.1580 0.0066 288 2 286 8 265 63 19 7 176 0.0628 0.0457 0.0003 0.3245 0.0067 0.0515 0.0011 0.0105 0.0001 0.0628 0.0003 288 2 285 6 261 48 20 7 145 0.9518 0.0455 0.0003 0.3269 0.0091 0.0522 0.0014 0.0105 0.0001 0.9518 0.0045 287 2 287 8 292 63 21 10 187 1.1754 0.0457 0.0003 0.3286 0.0066 0.0522 0.0010 0.0108 0.0000 1.1754 0.0031 288 2 288 6 294 45 22 8 165 1.0351 0.0443 0.0002 0.3760 0.0076 0.0616 0.0012 0.0094 0.0001 1.0351 0.0174 279 2 324 7 661 43 注: 表中所列误差均为 1σ误差; 2,1,2,4-21号点 206Pb/238U表面年龄加权平均值 287±1Ma 3. 讨论
研究区碱长花岗岩体与欧玉陶勒盖(Oyu Tol-goi)超大型斑岩型铜金矿邻近,前人将该岩体时代定为晚泥盆世[16],而对该岩体成岩时代的高精度同位素年龄测定尚未开展过系统的研究。本文采用高精度LA-ICP-MS锆石U-Pb原位定年技术,将普通铅较高的锆石排除,选取其他谐和度好的多颗锆石,获得该岩体的成岩年龄为286.00±0.91Ma(MSWD=1.4),所获数据可信度高,表明该碱长花岗岩体为早二叠世岩浆作用的产物。
研究区古生代处于岛弧向大陆板内过渡的构造区内,古亚洲洋板块俯冲、闭合不同阶段的挤压、松弛及后续的拉张作用使地壳内部不同深度的基底岩石发生平衡部分熔融,形成火山-侵入杂岩。岩浆作用表现为火山作用与侵入作用紧密伴随,火山岩和侵入岩相继产出,多旋回多期次的岩浆作用形成不同产出方式的岩浆岩,并在不同构造部位相应地引起不同的成矿作用,形成不同的矿床类型。其中与欧玉陶勒盖(Oyu Tolgoi)铜-金矿关系密切的石英闪长年龄为371±2Ma,花岗闪长岩的年龄约为365±2Ma[17-18];苏廷(Shuteen)斑岩型铜矿的花岗闪长岩Rb-Sr全岩同位素年龄为321±9Ma[19],可汗博格达(Khan Bogd)钼铌稀土矿床的碱性花岗岩Rb-Sr全岩等时线年龄为283-290Ma[20-21]。伴随该区多期次岩浆活动,与之密切相关的诸多大中型矿床也相继形成,其中以欧玉陶勒盖(Oyu Tolgoi)斑岩型铜-金矿床(成矿年龄为371±2Ma)、查干苏布尔加(Tsagaan Suvarga)斑岩型铜-钼矿床(成矿年龄为364.9±3.5Ma)、苏廷(Shuteen)斑岩型铜矿床(成矿年龄为321±9Ma)、可汗博格达(Khan Bogol)钽铌稀土矿床(成矿年龄为295±5.3Ma)[5-8]最为典型。本次对欧玉陶勒盖(Oyu Tolgoi)外围岩体的精确定年,确定了岩体的形成时代,不仅为该区多期次岩浆活动提供了直接的年龄证据,而且为与成岩关系密切的成矿作用提供了年代学依据,为该区找矿指明了方向。此外,该岩体内有不同程度的矿化蚀变作用,硅化、钾化、钠长石化、萤石化、绢云母化及褐铁矿化普遍发育,Mo(50~110g/t)、Zn(40~200g/t)、Cu(30~1180g/t)、Bi(20~30g/t)、W(0~20g/t)等岩石地球化学数据[22-23]①普遍高于其他围岩的成矿元素含量,而研究区及毗邻地区大量铜、金、银和稀有-稀土金属矿床、矿点的存在及该区多期次成岩、成矿特征表明,在研究区内寻找该时期稀有-稀土金属矿床仍大有希望,在地质找矿工作中应给予足够的重视。
4. 结论
(1)通过LA-ICP-MS高精度同位素测年技术,对蒙古欧玉陶勒盖(Oyu Tolgoi)南20km处的碱长花岗岩岩体进行锆石U-Pb定年,206Pb/238U年龄加权平均值为286.00±0.91Ma(MSWD=1.4),表明岩体形成于早二叠世,属于海西期构造-岩浆动的产物。
(2)研究区具有多期次成岩、成矿特征。本次定年不仅为该区多期次岩浆活动提供了直接的年龄证据,也为该区找矿指明了方向。
致谢: 野外工作期间得到蒙古地质调查局Otgonbaatar B,Tushigmaa Ch,Altankhundaga B等专家的协助,测试过程中中国地质调查局天津地质调查中心耿建珍工程师给予支持,在此一并表示感谢。 -
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图 1 蒙古Oyu Tolgoi外围地质简图
1—志留纪火山沉积地层;2—泥盆纪火山岩地层;3—石炭纪火山岩地层;4—白垩纪陆源沉积地层;5—新生代沉积地层;6—碱长花岗岩;7—花岗岩;8—断裂;9—Oyu Tolgoi斑岩型铜-金矿床;10—采样点
Figure 1. Simplified geological map of the periphery of Oyu Tolgoi, Mongolia
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图 2 蒙古Oyu Tolgoi碱长花岗岩野外照片
Figure 2. Main sample photos of alkalic feldspar granite in the peripheral Oyu Tolgoi, Mongolia
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图 3 蒙古Oyu Tolgoi外围二长花岗岩锆石阴极发光图像
Figure 3. CL images of monzogranite on the periphery of Oyu Tolgoi, Mongolia
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图 4 蒙古Oyu Tolgoi外围碱长花岗岩LA-ICP-MS锆石U-Pb谐和图
Figure 4. LA-ICP-MS zircon U-Pb concordia plots for monzogranite on the periphery of Oyu Tolgoi, Mongolia
表 1 蒙古Oyu Tolgoi外围碱长花岗岩LA-ICP-MS锆石U-Th-Pb分析测试结果
Table 1 LA-ICP-MS U-Th-Pb analytical data for zircons from alkalifeldspar granite on the periphery of Oyu Tolgoi, Mongolia
样品号 含量/10-6 Th/U 同位素比值 年龄/Ma MND105
TW1Pb U 206Pb/238U 1σ 207Pb/235U 1σ 207Pb/206Pb 1σ 208Pb/232Th 1σ 232Th/238U 1σ 206Pb/238U 1σ 207Pb/235U 1σ 207Pb/206Pb 1σ 1 13 252 1.1015 0.0452 0.0003 0.3256 0.0050 0.0522 0.0008 0.0110 0.0000 1.1015 0.0033 285 2 286 4 294 35 2 14 273 1.0760 0.0455 0.0002 0.3267 0.0080 0.0520 0.0013 0.0100 0.0001 1.0760 0.0037 287 2 287 7 287 55 3 8 143 0.9685 0.0489 0.0003 0.5628 0.0220 0.0835 0.0033 0.0151 0.0002 0.9685 0.0008 308 2 453 18 1282 76 4 16 297 1.3339 0.0454 0.0002 0.4120 0.0052 0.0658 0.0009 0.0107 0.0000 1.3339 0.0043 286 2 350 4 801 28 5 15 261 1.5262 0.0454 0.0003 0.4954 0.0052 0.0792 0.0008 0.0109 0.0001 1.5262 0.0229 286 2 409 4 1177 19 6 35 590 1.4658 0.0454 0.0003 0.5424 0.0058 0.0866 0.0007 0.0125 0.0001 1.4658 0.0233 286 2 440 5 1351 16 7 8 155 0.9604 0.0454 0.0003 0.3134 0.0076 0.0500 0.0012 0.0100 0.0001 0.9604 0.0033 286 2 277 7 196 56 8 14 165 1.0349 0.0454 0.0003 0.7935 0.0119 0.1267 0.0018 0.0418 0.0007 1.0349 0.0185 286 2 593 9 2053 25 9 12 221 0.8357 0.0454 0.0002 0.3254 0.0062 0.0520 0.0009 0.0156 0.0003 0.8357 0.0063 286 2 286 5 285 42 10 12 229 0.9812 0.0454 0.0003 0.4411 0.0077 0.0705 0.0012 0.0114 0.0001 0.9812 0.0065 286 2 371 6 943 36 11 14 247 1.5680 0.0454 0.0003 0.6633 0.0153 0.1059 0.0027 0.0104 0.0001 1.5680 0.0079 286 2 517 12 1731 46 12 9 142 0.8280 0.0454 0.0003 0.8101 0.0245 0.1295 0.0036 0.0220 0.0003 0.8280 0.0054 286 2 603 18 2091 49 13 11 195 1.3956 0.0453 0.0003 0.6111 0.0141 0.0979 0.0022 0.0110 0.0001 1.3956 0.0059 286 2 484 11 1584 43 14 11 212 0.9225 0.0455 0.0003 0.3264 0.0052 0.0520 0.0009 0.0106 0.0001 0.9225 0.0016 287 2 287 5 286 38 15 10 197 0.9360 0.0455 0.0003 0.3268 0.0054 0.0521 0.0009 0.0105 0.0001 0.9360 0.0091 287 2 287 5 289 40 16 9 191 0.3169 0.0454 0.0003 0.4219 0.0102 0.0674 0.0016 0.0111 0.0001 0.3169 0.0008 286 2 357 9 849 48 17 10 204 0.9624 0.0452 0.0003 0.3257 0.0058 0.0523 0.0009 0.0102 0.0001 0.9624 0.0134 285 2 286 5 298 39 18 6 122 1.1580 0.0458 0.0003 0.3252 0.0091 0.0515 0.0014 0.0106 0.0001 1.1580 0.0066 288 2 286 8 265 63 19 7 176 0.0628 0.0457 0.0003 0.3245 0.0067 0.0515 0.0011 0.0105 0.0001 0.0628 0.0003 288 2 285 6 261 48 20 7 145 0.9518 0.0455 0.0003 0.3269 0.0091 0.0522 0.0014 0.0105 0.0001 0.9518 0.0045 287 2 287 8 292 63 21 10 187 1.1754 0.0457 0.0003 0.3286 0.0066 0.0522 0.0010 0.0108 0.0000 1.1754 0.0031 288 2 288 6 294 45 22 8 165 1.0351 0.0443 0.0002 0.3760 0.0076 0.0616 0.0012 0.0094 0.0001 1.0351 0.0174 279 2 324 7 661 43 注: 表中所列误差均为 1σ误差; 2,1,2,4-21号点 206Pb/238U表面年龄加权平均值 287±1Ma 
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Perelló J, Cox D, Garamjav D, et al. Oyu Tolgoi, Mongolia:Siluro-Devonian porphyry Cu-Au-(Mo) and high sulfidation Cu mineral-ization with a Cretaceous chalcocite blanket[J]. Economic Geology, 2001, 96:1407. Perelló J, Cox D, Garamjav D, et al. Oyu Tolgoi, Mongolia:Siluro-Devonian porphyry Cu-Au-(Mo) and high sulfidation Cu mineral-ization with a Cretaceous chalcocite blanket[J]. Economic Geology, 2001, 96:1407.
Kirwin D J, Forster C N, Kavalierj S I, et al. The Oyu Tolgoi cop-per-gold deposit,South Gobi,Mongolia[C]//Seltmann R, Gerel O, Kirwin D J. Geodynamics and Metallogeny of Mongolia with a Spe-cial Emphasis on Copper and Gold Deposits. IAGOD Guidebook Series 11, London, 2005:155-174. Kirwin D J, Forster C N, Kavalierj S I, et al. The Oyu Tolgoi cop-per-gold deposit, South Gobi, Mongolia[C]//Seltmann R, Gerel O, Kirwin D J. Geodynamics and Metallogeny of Mongolia with a Spe-cial Emphasis on Copper and Gold Deposits. IAGOD Guidebook Series 11, London, 2005:155-174.
Wainwright A J. Volcanostrigraphic framework and magmatic evolu-tion of the Oyu Tolgoi Porphyry Cu-Au district[D].Vacouver:Uni-versity of British Columbia, 2008:272. Wainwright A J. Volcanostrigraphic framework and magmatic evolu-tion of the Oyu Tolgoi Porphyry Cu-Au district[D].Vacouver:Uni-versity of British Columbia, 2008:272.
Watanabe Y, Stein H J. Re-Os ages for the Erdenet and Tsagaan Su-varga porphyry Cu-Mo deposits, Mongolia, and tectonic implica-tions[J]. Economic Geology, 2000, 95:1537-1542. Watanabe Y, Stein H J. Re-Os ages for the Erdenet and Tsagaan Su-varga porphyry Cu-Mo deposits, Mongolia, and tectonic implica-tions[J]. Economic Geology, 2000, 95:1537-1542.
Dejidmaa G, Badarch G. Summary of preaccretiobary and accretion-ary metallogenic belts of Mongolia[C]//Seltmann R, Gerel O, Kir-win D J. Geodynamics and Metallogeny of Mongolia with a Special Emphasis on Copper and Gold Deposits. IAGOD Guidebook Series 11, London, 2005:25-30. Dejidmaa G, Badarch G. Summary of preaccretiobary and accretion-ary metallogenic belts of Mongolia[C]//Seltmann R, Gerel O, Kir-win D J. Geodynamics and Metallogeny of Mongolia with a Special Emphasis on Copper and Gold Deposits. IAGOD Guidebook Series 11, London, 2005:25-30.
Dejidmaa G. Mineral Resources and Metallogenic Belts in southern-Mongolia[C]//Seltmann R, Gerel O, Kirwin D J. Geodynamics and Metallogeny of Mongolia with a Special Emphasis on Copper and Gold Deposits. IAGOD Guidebook Series 11,London, 2005:149-153 Dejidmaa G. Mineral Resources and Metallogenic Belts in southern-Mongolia[C]//Seltmann R, Gerel O, Kirwin D J. Geodynamics and Metallogeny of Mongolia with a Special Emphasis on Copper and Gold Deposits. IAGOD Guidebook Series 11, London, 2005:149-153
Dejidmaa G, Dorjgotov D, Gerel O, et al. Preliminary description of mineral deposit models (types) for Mongolia[C]//Seltmann R, Gerel O, Kirwin D J. Geodynamics and Metallogeny of Mongolia with a Special Emphasis on Copper and Gold Deposits. IAGOD Guide-book Series 11, London, 2005:31-52. Dejidmaa G, Dorjgotov D, Gerel O, et al. Preliminary description of mineral deposit models (types) for Mongolia[C]//Seltmann R, Gerel O, Kirwin D J. Geodynamics and Metallogeny of Mongolia with a Special Emphasis on Copper and Gold Deposits. IAGOD Guide-book Series 11, London, 2005:31-52.
李俊建, 张峰, 任军平, 等.中蒙边界地区构造单元划分[J].地质通报, 2015, 34(4):636-662. Vladykin N V, Kovalenko V I, Dorfman M D. Mineralogy and Geochemistry of the Khan Bogd Alkali Granitoid Pluton (People's Republic of Mongolia)[M]. Nauka, Moscow, 1981. Vladykin N V, Kovalenko V I, Dorfman M D. Mineralogy and Geochemistry of the Khan Bogd Alkali Granitoid Pluton (People's Republic of Mongolia)[M]. Nauka, Moscow, 1981.
Durante M V, Zonenshain L P, Goreglyad A V, et al. Geological Position of the Khan Bogd Alkaline Pluton in People's Republic of Mongolia[J]. Byull. Mosk. Ova Ispyt. Prir., Otd. Geol., 1976, 4:85-104. Durante M V, Zonenshain L P, Goreglyad A V, et al. Geological Position of the Khan Bogd Alkaline Pluton in People's Republic of Mongolia[J]. Byull. Mosk. Ova Ispyt. Prir., Otd. Geol., 1976, 4:85-104.
Sandimirova G P, Plyusnin G S, Kovalenko V I, et al. Rb-Sr Dat-ing of Alkali Granites in the Khan Bogd Pluton in the People's Re-public of Mongolia[J]. Geol. Geofiz.,1980, 21(2):150-154. Sandimirova G P, Plyusnin G S, Kovalenko V I, et al. Rb-Sr Dat-ing of Alkali Granites in the Khan Bogd Pluton in the People's Re-public of Mongolia[J]. Geol. Geofiz., 1980, 21(2):150-154.
Yarmolyuk V V, Durante M V, Kovalenko V I, et al. Age of co-mendite-alkali granite rock association in southern Mongolia[M]. Izv. Akad. Nauk SSSR, Ser. Geol.,1981, 9:40-48. Yarmolyuk V V, Durante M V, Kovalenko V I, et al. Age of co-mendite-alkali granite rock association in southern Mongolia[M]. Izv. Akad. Nauk SSSR, Ser. Geol., 1981, 9:40-48.
Hu Z C, Gao S, Liu Y S, et al. Signal Enhancement in Laser Ab-lation ICP-MS by Addation of Nitrogen in the Central Channel Gas[J]. Journal of Analytical Atomic Spectrometry, 2008, 23:1093-1101. Hu Z C, Gao S, Liu Y S, et al. Signal Enhancement in Laser Ab-lation ICP-MS by Addation of Nitrogen in the Central Channel Gas[J]. Journal of Analytical Atomic Spectrometry, 2008, 23:1093-1101.
李怀坤, 耿建珍, 郝爽, 等.用激光烧蚀多接收器等离子体质谱仪(LA-ICP-MS)测定锆石U-Pb同位素年龄的研究[J].矿物学报, 2009, 1(增刊):77. Claesson S V, Vertin B, Ayanova H D. U-Pb zircon ages from a Devonian carbonatite dyke, Kola peninsula, Russia:a record of geo-logical evolution from the Archaen the Palaeozoic[J]. Lithos, 2000, 51:95-108. Claesson S V, Vertin B, Ayanova H D. U-Pb zircon ages from a Devonian carbonatite dyke, Kola peninsula, Russia:a record of geo-logical evolution from the Archaen the Palaeozoic[J]. Lithos, 2000, 51:95-108.
Mineral Resources Authority of Mongolia and Mongolian Acade-my of Sciences (MRAM-MAS). Geological Map of Mongolia(at the Scale 1:1000000) and its explanatory note[M]. Ulaanbaatar, 1998:4-20. Mineral Resources Authority of Mongolia and Mongolian Acade-my of Sciences (MRAM-MAS). Geological Map of Mongolia(at the Scale 1:1000000) and its explanatory note[M]. Ulaanbaatar, 1998:4-20.
Kirwin D J, Wilson C C, Turmagnai D, et al. Exploration history, geology and mineralization of the Kharmagtai gold-copper porphy-ry district, South Gobi region, Mongolia[C]//Seltmann R, Gerel O, Kirwin D J. Geodynamics and Metallogeny of Mongolia with a Special Emphasis on Copper and Gold Deposits. IAGOD Guide-book Series 11, London, 2005:175-192. Kirwin D J, Wilson C C, Turmagnai D, et al. Exploration history, geology and mineralization of the Kharmagtai gold-copper porphy-ry district, South Gobi region, Mongolia[C]//Seltmann R, Gerel O, Kirwin D J. Geodynamics and Metallogeny of Mongolia with a Special Emphasis on Copper and Gold Deposits. IAGOD Guide-book Series 11, London, 2005:175-192.
Wainwright A J, Tosdal R M, Wooden J L, et al. U-Pb (zircon) and geochemical constraints on the age, origin, and evolution of Pa-leozoic arc magmas in the Oyu Tolgoi porphyry Cu-Au district, southern Mongolia[J]. Gondwana Research, 2011, 19:764-787. Wainwright A J, Tosdal R M, Wooden J L, et al. U-Pb (zircon) and geochemical constraints on the age, origin, and evolution of Pa-leozoic arc magmas in the Oyu Tolgoi porphyry Cu-Au district, southern Mongolia[J]. Gondwana Research, 2011, 19:764-787.
Batkhishig B, Lizumi S. Petrographical, petrochemical and geochro-nological study of the Carboniferous Shuteen complex in South Mongolia[J]. Mongolian Geol., 2001, 2:135-145. Batkhishig B, Lizumi S. Petrographical, petrochemical and geochro-nological study of the Carboniferous Shuteen complex in South Mongolia[J]. Mongolian Geol., 2001, 2:135-145.
Kovalenko V I, Yarmoluyk V V, Sal'nikova E B. Geology, Geo-chronology and Geodynamics of the Khan Bogd Alkali Granite Plu-ton in Southern Mongolia[J]. Geotectonics, 2006, 40(6):450-466. Kovalenko V I, Yarmoluyk V V, Sal'nikova E B. Geology, Geo-chronology and Geodynamics of the Khan Bogd Alkali Granite Plu-ton in Southern Mongolia[J]. Geotectonics, 2006, 40(6):450-466.
Gerel O, Oyungerel S, Minjin Ch. Intrusive magmatism of South Mongolia[C]//Seltmann R, Gerel O, Kirwin D J. Geodynamics and Metallogeny of Mongolia with a Special Emphasis on Copper and Gold Deposits. IAGOD Guidebook Series11, London, 2005:131-147. Gerel O, Oyungerel S, Minjin Ch. Intrusive magmatism of South Mongolia[C]//Seltmann R, Gerel O, Kirwin D J. Geodynamics and Metallogeny of Mongolia with a Special Emphasis on Copper and Gold Deposits. IAGOD Guidebook Series11, London, 2005:131-147.
Bignall G, Batkhishig B, Tsuchiya. The Shuteen Cu-Au porphyry deposit[C]//Seltmann R, Gerel O, Kirwin D J. Geodynamics and Metallogeny of Mongolia with a Special Emphasis on Copper and Gold Deposits. IAGOD Guidebook Series 11, London, 2005:193-202. Bignall G, Batkhishig B, Tsuchiya. The Shuteen Cu-Au porphyry deposit[C]//Seltmann R, Gerel O, Kirwin D J. Geodynamics and Metallogeny of Mongolia with a Special Emphasis on Copper and Gold Deposits. IAGOD Guidebook Series 11, London, 2005:193-202.
Stein H J. Oyut Tolgoi PIMA study. Report to Ivanhoe Mines Limited.2003.
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