内蒙古东珺铅锌银矿床闪锌矿Rb-Sr定年及其地质意义

热液脉型铅锌多金属矿床是内蒙古得尔布干成矿带一重要矿床类型,由于缺乏适当的定年方法,该类矿床的成矿年龄及其形成的地质背景一直不明确。东珺铅锌银矿床是一新近发现的热液脉型矿床,本文在对采自该矿床的6件闪锌矿矿石样品进行了结构构造研究的基础上,对闪锌矿的Rb-Sr同位素进行了分析。结果表明,闪锌矿87 Rb/86 Sr和87 Sr/86 Sr同位素比值均有较大的分布范围,分别分布在0.283 8~6.503 0和0.713 685~0.725 241范围内,二者具有很好的线性关系,构成的等时线年龄为(130.2±4.4)Ma(2σ,MSWD=16),(87Sr/86Sr)0=0.713 176±0.000 057,指示矿床形成于早白垩世。早白垩世大兴安岭地区处于伸展构造体制,因此该类矿床是在拉张构造体制的背景下形成的,与区内早白垩世浅成-超浅成岩浆侵入活动有关,它代表了区内一重要成矿阶段与成矿类型。     

大兴安岭北部甲乌拉铅锌银矿床Rb-Sr同位素测年及其地质意义

甲乌拉铅锌银矿床位于内蒙古自治区满洲里市南西150km。矿床产于中蒙古-额尔古纳兴凯造山带南东缘之得尔布干断裂北西侧。本文在甲乌拉矿床选取7件闪锌矿和6件黄铁矿样品开展了Rb-Sr定年。获得闪锌矿的Rb-Sr等时线年龄为143.0±2.0Ma(MSWD=3.2),锶同位素初始值I Sr=0.71265;黄铁矿的Rb-Sr等时线年龄为142.0±3.0Ma(MSWD=5.7),锶同位素初始值ISr=0.71267;闪锌矿与黄铁矿的Rb-Sr等时线年龄为142.7±1.3Ma(MSWD=3.8),锶同位素初始值ISr=0.71266。上述定年结果表明,甲乌拉矿床形成于早白垩世初期。甲乌拉矿床硫化物的Rb和Sr含量分别介于0.1034×10-6～7.367×10-6和1.301×10-6～7.148×10-6之间,Sr同位素初始比值(87Sr/86Sr)i介于0.71238～0.71277之间,平均值为0.71264,暗示甲乌拉矿床的成矿物质主要来源于地壳。甲乌拉矿床形成于蒙古-鄂霍茨克造山过程的后碰撞阶段。     

云南保山金厂河铁铜铅锌多金属矿床Rb-Sr等时线测年及其地质意义

金厂河铁铜铅锌多金属矿床位于保山地块北部、NS向保山-施甸复背斜与NNW向澜沧江断裂锐角交汇部位的南部。矿体呈层状、似层状产于寒武系核桃坪组金厂河背斜的层间裂隙中,受NW向、NE向断裂交汇处的控制。选取闪锌矿及其共生的方铅矿、黄铜矿、石英样品,应用Rb-Sr同位素测年方法,获得闪锌矿等时线年龄为(118.9±5.9)Ma,闪锌矿+方铅矿等时线年龄为(119.3±1.7)Ma,闪锌矿+黄铜矿等时线年龄为(120.3±5.1)Ma,闪锌矿+石英等时线年龄为(117.0±2.4)Ma,闪锌矿+方铅矿+石英等时线年龄为(118.7±1.5)Ma,闪锌矿+方铅矿+黄铜矿等时线年龄为(119.6±1.6)Ma,闪锌矿+方铅矿+黄铜矿+石英等时线年龄为(118.9±1.4)Ma。Rb-Sr定年结果表明,金厂河铁铜铅锌多金属矿床的成矿时代为117~120 Ma,为早白垩世。热液矿物组合的(87Sr/86Sr)i平均值为0.713 885,与保山地块内志本山岩体的(87Sr/86Sr)i值接近,指示其成矿物质主要来源于地壳,成矿作用与保山地块内燕山晚期花岗岩岩浆活动有关,结合矿区重力负异常特点,推测矿区内存在隐伏的中-酸性岩体。通过地球动力学背景探讨,认为该矿床的形成可能是对中特提斯洋闭合过程中腾冲地块与保山地块碰撞造山作用的响应,与地块内部受碰撞影响而导致地壳深熔所产生的岩浆作用有关。     

广东天堂铜铅锌多金属矿床Rb-Sr等时线年龄及其地质意义

文章选取8件闪锌矿、3件方铅矿和1件黄铁矿样品,采用Rb-Sr等时线定年方法测定天堂铜铅锌多金属矿床的成矿时代.获得闪锌矿等时线年龄为(98.1±1.6) Ma,闪锌矿+方铅矿等时线年龄为(99±2)Ma,闪锌矿+方铅矿+黄铁矿等时线年龄为(98.2±1.3) Ma,闪锌矿+黄铁矿等时线年龄为(97.87±0.96) Ma,方铅矿+黄铁矿等时线年龄为(98.6±4.2) Ma.Rb-Sr定年结果表明,天堂铜铅锌多金属矿床的成矿时代为98 Ma左右,矿床形成于晚白垩世早期,可能与135Ma之后太平洋板块的运动方向发生转向,使得中国大陆包括华南板块在内均处于持续伸展阶段有关.硫化物矿石Rb-Sr所得的Sr同位素初始比(87Sr/86Sr)i平均值为0.7117,小于陆源硅酸盐的值(0.720),高于地幔Sr的初始值0.707,结合笔者对该矿床所做的S、Pb等同位素组成特征研究,显示成矿物质来源于壳幔混合.研究表明,利用特定矿床的主要矿石矿物,采用Rb-Sr等时线定年方法通过共生矿物组合和单矿物相互约束,可以有效地确定成矿时代,这对了解矿床的成矿背景等具有一定的指示意义.     

云南镇康芦子园铅-锌矿的成矿年龄

芦子园铅锌矿为保山-镇康地块中一个重要的热液矿床。矿床赋存于早古生代碳酸盐岩中,经人工分选出矿石中的闪锌矿、黄铜矿、与矿石硫化物密切共生的热液石英及石英钾长石脉中的钾长石等共10件单矿物样品,采用Rb-Sr同位素定年分析,获得等时线年龄141.9±2.6 Ma,初始锶同位素组成为87Sr/86Sr(t=141.9 Ma)=0.714 497。揭示成矿作用时代与中特提斯怒江洋闭合时期大致相当,矿石初始锶同位素组成也与保山-镇康地块中燕山期花岗岩初始Sr同位素组成基本一致,指示矿床的成因可能与燕山期岩浆活动有关,是中特提斯怒江洋闭合过程中碰撞造山作用的响应。     

内蒙古兴和县曹四夭超大型斑岩钼铅锌金成矿系统年代学及其地质意义

曹四夭斑岩钼矿床位于内蒙古兴和县,是华北克拉通北缘最大的钼矿床。该矿床中部发育斑岩型钼矿体,外围和上部产出热液脉型铅锌金矿体。文章选取1件与斑岩钼矿化共生的绢云母样品进行了40Ar-39Ar定年,获得40Ar-39Ar坪年龄为(144.4±1.2)Ma,相应的39Ar/36Ar-40Ar/39Ar等时线年龄为(146.4±2.2)Ma(MSWD=0.31),将等时线年龄认作绢云母的Ar封闭年龄,表明曹四夭斑岩钼矿化发生在约146 Ma前。选取14件脉型铅锌矿石中的闪锌矿、黄铁矿和磁黄铁矿样品开展了Rb-Sr定年,获得4件闪锌矿的Rb-Sr等时线年龄为(145.1±3.0)Ma(MSWD=0.63);5件黄铁矿的Rb-Sr等时线年龄为(145.2±1.3)Ma(MSWD=0.53);4件闪锌矿、5件黄铁矿和1件磁黄铁矿的Rb-Sr等时线年龄为(145.3±1.0)Ma(MSWD=0.43)。硫化物Rb-Sr定年结果表明曹四夭矿床脉型铅锌矿化形成于约145 Ma前。本次绢云母40Ar-39Ar和硫化物Rb-Sr定年结果表明,曹四夭矿床斑岩型钼矿化和脉型铅锌金矿化为同期产物,两者均形成于晚侏罗世末期,属于同一个斑岩成矿系统。曹四夭矿床硫化物的w(Rb)和w(Sr)分别为0.1867×10~(-6)~1.305×10~(-6)和0.3175×10~(-6)~6.935×10~(-6),Sr同位素初始比值(87Sr/86Sr)i介于0.709 919~0.711 951之间,平均值0.710 952,结合前人获得的辉钼矿Re含量,认为曹四夭矿床的成矿物质主要来源于地壳。     

云南保山金厂河铁铜铅锌多金属矿床Rb-Sr等时线测年及其地质意义

金厂河铁铜铅锌多金属矿床位于保山地块北部、NS向保山-施甸复背斜与NNW向澜沧江断裂锐角交汇部位的南部。矿体呈层状、似层状产于寒武系核桃坪组金厂河背斜的层间裂隙中,受NW向、NE向断裂交汇处的控制。选取闪锌矿及其共生的方铅矿、黄铜矿、石英样品,应用Rb-Sr同位素测年方法,获得闪锌矿等时线年龄为（118.9±5.9） Ma,闪锌矿+方铅矿等时线年龄为（119.3±1.7） Ma,闪锌矿+黄铜矿等时线年龄为（120.3±5.1） Ma,闪锌矿+石英等时线年龄为（117.0±2.4） Ma,闪锌矿+方铅矿+石英等时线年龄为（118.7±1.5） Ma,闪锌矿+方铅矿+黄铜矿等时线年龄为（119.6±1.6） Ma,闪锌矿+方铅矿+黄铜矿+石英等时线年龄为（118.9±1.4） Ma。Rb-Sr定年结果表明,金厂河铁铜铅锌多金属矿床的成矿时代为117~120 Ma,为早白垩世。热液矿物组合的 （⁸⁷Sr/⁸⁶Sr）_i平均值为0.713?885,与保山地块内志本山岩体的（⁸⁷Sr/⁸⁶Sr）_i值接近,指示其成矿物质主要来源于地壳,成矿作用与保山地块内燕山晚期花岗岩岩浆活动有关,结合矿区重力负异常特点,推测矿区内存在隐伏的中-酸性岩体。通过地球动力学背景探讨,认为该矿床的形成可能是对中特提斯洋闭合过程中腾冲地块与保山地块碰撞造山作用的响应,与地块内部受碰撞影响而导致地壳深熔所产生的岩浆作用有关。     

滇东北毛坪铅锌矿床的成矿时代:闪锌矿Rb-Sr定年

毛坪铅锌矿床是滇东北地区代表性矿床之一,目前尚缺乏精确的成矿年代学数据。该文对选自块状铅锌矿石的4件闪锌矿单矿物样品进行了Rb-Sr同位素定年,获得等时线年龄为321.7±5.8 Ma(MSWD=1.5),表明毛坪铅锌矿床的主成矿作用发生于石炭纪。此外,闪锌矿~(87)Sr/~(86)Sr初始值为0.712166±0.000017,低于大陆地壳~(87)Sr/~(86)Sr平均值(0.719)且高于地幔Sr初始值(0.707),暗示成矿物质主要来源于大陆地壳并混有少量地幔物质。综合前人研究成果,作者认为毛坪铅锌矿属后生矿床,与晚二叠世峨眉山大火成岩省玄武岩浆活动无成因联系,类似于典型的MVT矿床,且滇东北地区可能发育多期铅锌矿化作用。     

豫西骆驼山多金属硫铁矿床硫化物Rb-Sr等时线年龄及其地质意义

豫西骆驼山多金属硫铁矿床位于华北陆块南缘南泥湖矿田西北侧。为确定该矿床的形成时代,文章选取了8件硫化物矿物样品,采用Rb_Sr等时线定年方法测定成矿年龄。结果获得,闪锌矿+磁黄铁矿+方铅矿等时线年龄为(137.3±2.6)Ma,闪锌矿+方铅矿等时线年龄为(138.2±5.8)Ma,闪锌矿+磁黄铁矿等时线年龄为(137±3)Ma,磁黄铁矿+方铅矿等时线年龄为(137.1±2.7)Ma,方铅矿等时线年龄为(138.4±7.6)Ma,磁黄铁矿等时线年龄为(137.2±3.7)Ma。上述定年结果表明,骆驼山多金属硫铁矿床的成矿时代为137 Ma左右,属早白垩世。硫化物Sr同位素初始比值(~(87)Sr/~(86)Sr)i介于0.713 23~0.713 32,平均值为0.713 25,小于陆源硅酸盐Sr的初始值0.7190,而高于地幔Sr的初始值0.7040,表明成矿物质来源于壳幔混合。骆驼山多金属硫铁矿床与矿田内的南泥湖_三道庄斑岩_矽卡岩钼(钨)矿床、冷水北沟铅锌矿成矿时代基本一致,是同一构造_岩浆_流体成矿活动的产物。结合前人对华北陆块南缘中生代期间地球动力学背景研究成果,笔者认为骆驼山矿床是中国东部中生代构造体制大转折过程晚期的产物。     

云南茂租铅锌矿床闪锌矿Rb-Sr同位素组成与地质意义

茂租铅锌矿床位于云南省东北部,赋存于上震旦统灯影组白云岩中,矿体主要呈似层状和脉状,矿石主要由闪锌矿、方铅矿、黄铁矿和方解石等组成。应用TIMS对选自茂租铅锌矿床主成矿期的5件闪锌矿单矿物进行了Rb-Sr同位素组成分析。结果显示,全部闪锌矿样品的Rb含量较低(0.05×10-6~0.18×10-6),Sr含量亦不高(0.33×10-6~10.02×10-6),87Rb/86Sr值变化范围较小,为0.052~0.850,87Sr/86Sr值较高,变化范围为0.7117~0.7210。虽然本次分析结果未获得理想的Rb-Sr等时线年龄,但根据年龄(200 Ma)校正后的87Sr/86Sr值(0.7106~0.7186),具有示踪成矿流体/物质来源的重要意义。与赋矿灯影组白云岩、区域寒武—二叠系沉积岩、峨眉山玄武岩和元古代基底岩石(昆阳群、会理群等)的87Sr/86Sr200 Ma值相比,茂租闪锌矿87Sr/86Sr值明显高于除基底岩石外的其它地质体,表明茂租铅锌矿床成矿流体可能来源或流经了基底岩石,并与来源或流经盖层岩石的流体发生了混合。结合前人资料,本文认为流体混合作用是导致茂租铅锌矿床形成的重要机制,加强流体运移途径的研究,对寻找新的矿体具有重要的理论指导意义。     

Rb–Sr Dating of Gold‐bearing Pyrites from Wulaga Gold Deposit and its Geological Significance

Wulaga epithermal gold deposit is located in northeast China. Gold mineralization mainly occurs within the crypto‐explosive breccia belt of subvolcanic intrusion. Constraints on the precise timing of mineralization are of fundamental importance for understanding the ore genesis of the Wulaga gold deposit and its mineralization potential. Three hydrothermal stages have been identified: the early veiny quartz–euhedral pyrite stage; the fine pyrite–marcasite–gray or black chalcedony stage; and the late carbonate–pyrite stage. The Rb–Sr dating of gold‐bearing pyrites from the fine pyrite–marcasite–gray or black chalcedony stage is 113.8 ± 4.4 Ma with an initial ⁸⁷Sr/⁸⁶Sr ratio of 0.706346 ± 0.000019. The age of the gold deposit is consistent with the age of ore‐bearing volcanic (109–113 Ma) and subvolcanic intrusion (103–112 Ma) within the error limits, and the pyrite initial ratio has an identical value of ⁸⁷Sr/⁸⁶Sr to subvolcanic intrusion (0.705547 ± 0.000012). These indicate that crystallization of the wall rock and epithermal gold mineralization was coeval and likely cogenetic. Moreover, a lot of epithermal gold deposits that formed in Early Cretaceous volcanic and subvolcanic intrusions have been discovered in recent years in Heilongjiang province. Combined with the studies of tectonic and magmatic activities, we propose that the formation of the Wulaga gold deposit might be caused by the heated circum‐flow water related to the volcanic–subvolcanic intrusive hydrothermal event triggered by the ancient subduction of the Izanagi plate in the Early Cretaceous.     

U–Pb zircon,geochemical and Sr–Nd–Hf isotopic constraints on age and origin of the intrusions from Wunugetushan porphyry deposit,Northeast China: implication for Triassic–Jurassic Cu–Mo mineralization in Mongolia–Erguna metallogenic belt

The Wunugetushan porphyry Cu–Mo deposit is located in northeastern China. The deposit lies within the Mongolia–Erguna metallogenic belt, which is associated with the evolution of the Mongol–Okhotsk Ocean. The multiple episodes of magmatism in the ore district, occurred from 206 to 173 Ma, can be divided into pre-mineralization stage (biotite granite), mineralization stage (monzogranitic porphyry and rhyolitic porphyry), and post-mineralization stage (andesitic porphyry). The biotite granite has (⁸⁷Sr/⁸⁶Sr)_i values of 0.704105–0.704706, ε_Nd(t) values of ?0.67 to ?0.07, and ε_Hf(t) values of ?0.4 to 2.8, yielding Hf two-stage model ages (T_DM2) 1250–1067 Ma, and Nd model ages of 1.04–0.96 Ga, indicating that the pre-mineralization magmas were generated by the remelting of Neoproterozoic juvenile crustal material. The monzogranitic porphyry has (⁸⁷Sr/⁸⁶Sr)_i values of 0.704707–0.706134, ε_Nd(t) values of 0.29–1.33, and ε_Hf(t) values of 1.0–2.9, yielding T_DM2 model ages of 1173–1047 Ma. The rhyolitic porphyry has (⁸⁷Sr/⁸⁶Sr)_i ratio of 0.702129, ε_Nd(t) value of ?0.21, and ε_Hf(t) values of ?0.5 to 7.1, T_DM2 model ages from 1269 to 782 Ma. These results show that the magmas of mineralization stage were generated by the partial melting of juvenile crust mixed with mantle-derived components. The andesitic porphyry has (⁸⁷Sr/⁸⁶Sr)_i ratio of 0.705284, ε_Nd(t) value of 0.82, and ε_Hf(t) values from 4.1 to 7.4, indicating that the post-mineralization magma source contained more mantle-derived material. The Mesozoic Cu–Mo deposits which genetically related to Mongol–Okhotsk Ocean were temporally distributed in Middle to Late Triassic (240–230 Ma), Early Jurassic (200–180 Ma), and Later Jurassic (160–150 Ma) period. The Middle Triassic to Early Jurassic Cu–Mo mineralization was dominated by Mongol–Okhotsk oceanic plate southeast-directed subducted beneath the Erguna massif. The Later Jurassic Cu–Mo mineralization was controlled by the continent–continent collision between Siberia plate and Erguna massif.     

Rb–Sr dating of sulfides and S–Pb isotopic study of the Bayanbaolege Ag polymetallic deposit,Inner Mongolia,NE China

The large-scale Bayanbaolege Ag polymetallic deposit is situated in the Tuquan–Linxi Fe-Sn-Cu-Pb-Zn-Ag metallogenic sub-belt in eastern slopes of the southern Great Xing’an Range, NE China. The sulfide-quartz vein-type orebodies in the deposit are hosted primarily in the Early Cretaceous granodiorite porphyry and Late Permian strata. Three primary paragenetic stages of veining have been identified: (I) arsenopyrite- pyrite-quartz stage, (II) pyrite-sphalerite-quartz stage, and (III) galena-silver minerals (pyrargyrite, argentite, and pearceite)-calcite stage. The Rb–Sr dating of sulfides yielded an isochron age of 129.9 ± 2.9 Ma (MSWD = 2.1) for the sphalerite, which constrains the mineralization age to the Early Cretaceous. Rb and Sr concentrations in the sulfides ranged from 0.0940 to 1.0294 ppm and 0.0950–3.3818 ppm, respectively. The initial ⁸⁷Sr/⁸⁶Sr value of the sphalerite was 0.70852 ± 0.00018, indicating that the mineralized materials were derived from the mixed crust-mantle source area. S isotope analysis showed that the δ³⁴S values of the sulfide samples varied in a narrow range, from −1.5‰ to +1.3‰ (mean −0.65‰), indicating a magmatic S source. Pb isotopic ratios of the sulfides (²⁰⁶Pb/²⁰⁴Pb = 18.306–18.416, ²⁰⁷Pb/²⁰⁴Pb = 15.524–15.605, ²⁰⁸Pb/²⁰⁴Pb = 38.095–38.479) and the granodiorite porphyry (²⁰⁶Pb/²⁰⁴Pb = 18.341–18.933, ²⁰⁷Pb/²⁰⁴Pb = 15.539–15.600, ²⁰⁸Pb/²⁰⁴Pb = 38.134–38.944) reflect that the ore-forming materials originated from contemporaneous magma with Early Cretaceous granodiorite porphyry. This study of the Bayanbaolege deposit and other hydrothermal deposits in the area provides compelling evidence that the widespread Mesozoic magmatism and mineralization in the southern Great Xing’an Range occurred in an intracontinental extensional tectonic setting, which was associated with the westward subduction of the paleo-Pacific plate.     

额尔古纳地块新元古代花岗岩榍石原位微区LA- ICP- MS U- Pb定年及其地质意义

本文首次报道了额尔古纳地块新元古代花岗岩榍石原位微区LA-ICP-MS U-Pb定年数据,以明确其形成时代,进而为准确厘定额尔古纳地块新元古代岩浆作用期次提供新的证据,并进一步揭示其地质意义。研究区内分别采自满归岩体和莫尔道嘎岩体的2个代表性样品中的榍石呈菱形自形—半自形晶,不具有变质榍石特有的杏仁孔或孔洞特征,暗示其为岩浆成因。对原生榍石的定年结果显示,满归岩体和莫尔道嘎岩体数据点的线性拟合性均较好,拟合线下交点年龄分别为873±22 Ma和783±31 Ma,均与~(206)Pb/~(238)U加权平均年龄(872±18Ma和789±17 Ma)相一致。同时结合已有研究成果表明,原定为额尔古纳地块新元古代最早期岩浆作用产物的满归岩体实际形成于～850 Ma,而非前人认为的957～927 Ma;莫尔道嘎岩体形成于～790 Ma,也并非前人认为的～762 Ma。综合校正后的岩体年龄以及近年来前人研究成果,现阶段额尔古纳地块新元古代岩浆作用期次可大致分为五个阶段,即915～905 Ma、～847 Ma、818～808 Ma、～792 Ma和～738 Ma。     

云南水头山铅锌矿床闪锌矿Rb-Sr定年及其地质意义

水头山铅锌矿床位于保山地块南端芦子园矿集区,区内以发育矽卡岩型和热液脉型两类铅锌矿化为特点.为查明铅锌多金属成矿作用过程,本文对水头山热液脉型铅锌矿床主成矿阶段的闪锌矿开展了Rb-Sr同位素组成测定,获得闪锌矿的Rb-Sr等时线年龄为135.8±4.2Ma(MSWD=1.70,n=6),结合区内其他矿床的成矿年龄,认为...     

Genesis of Pb–Zn Mineralization Beneath the Xiangshan Uranium Orefield,South China: Constraints from H–O–S–Pb Isotopes and Rb–Sr Dating

The volcanic‐hosted Xiangshan uranium orefield is the largest uranium deposit in South China. Recent exploration has discovered extensive Pb–Zn mineralization beneath the uranium orebodies. Detailed geological investigation reveals that the major metallic minerals include pyrite, sphalerite, galena, and chalcopyrite, whilst the major non‐metallic minerals include quartz, sericite, and calcite. New δ¹⁸O_fluid and δD_fluid data indicate that the ore‐forming fluids were mainly derived from magmatic, and the sulfide δ³⁴S values (2.2–6.9‰) suggest a dominantly magmatic sulfur source. The Pb isotope compositions are homogeneous (²⁰⁶Pb/²⁰⁴Pb = 18.120–18.233, ²⁰⁷Pb/²⁰⁴Pb = 15.575–15.698, and ²⁰⁸Pb/²⁰⁴Pb = 37.047–38.446). The ⁸⁷Sr/⁸⁶Sr ratios of sulfide minerals range from 0.7197 to 0.7204, which is much higher than volcanic rocks and fall into the range of metamorphic basement. Lead and strontium isotopic compositions indicate that the metallogenic materials probably were derived from metamorphic basement. Pyrite Rb–Sr dating of the ores yielded 131.3 ± 4.0 Ma, indicating that the Pb–Zn mineralization occurred in the Early Cretaceous.