花岗岩浆侵位与结晶固化时差的研究与构造意义:以南岭骑田岭花岗岩基为例

通过对南岭中段骑田岭花岗岩基地质-岩石地球化学特征研究, 判明了该岩基的侵位深度（5.5 km）、围岩温度（196℃）及岩浆初始温度（950 ℃ ）,建立起骑田岭花岗岩基的数学计算模型,计算得出： 骑田岭花岗岩熔体侵位后,其初始温度降低至结晶温度所需的时间（Δt col） 为4.1 Ma;由于结晶潜热释放而使结晶过程延长的时间（Δt L）为2.6 Ma; 由于骑田岭花岗岩基放射性元素含量 （U-15.3×10-6,Th-51.35×10-6,K2O-5.02%）是世界平均花岗岩放射性元素含量（U-5×10-6,Th-20×10-6,K2O-2.66%）的2~3 倍,骑田岭花岗岩浆侵位后产生的放射成因热使结晶过程延长的时间（Δt A） 为35.4 Ma,远长于世界平均花岗岩计算的Δt A（2.93 Ma） 。因此, 骑田岭花岗岩基的岩浆侵位- 结晶固化时差 （Δt ECTD）为42.1 Ma, 结合锆石U-Pb 年龄值（161 Ma）, 通过反演计算得出骑田岭花岗岩基侵位年龄值（t E ）为203.1 Ma,从而为骑田岭花岗岩基属于印支期侵位提供了重要的岩浆动力学佐证。     

藏南冈底斯岩基日多地区花岗岩体形成时代和地球化学特征

冈底斯岩基广泛发育三叠纪-中新世的岩浆岩,是研究与新特提斯洋北向俯冲和印度-欧亚大陆碰撞相关的构造岩浆作用特征的天然实验室。日多地区花岗岩体位于藏南墨竹工卡县东侧日多乡附近,其主体为花岗岩,被花岗闪长玢岩脉侵入。锆石U-Pb地质年代学表明:主体花岗岩形成于62.7±0.5Ma,侵入其中的花岗闪长玢岩脉形成于59.5±1.5Ma,并捕获了大量的侏罗纪岩浆岩锆石(155.4±1.8Ma)。日多地区花岗岩体的全岩地球化学特征为:(1)高Si O_2、Na_2O、Al_2O_3,低Fe O~T、MgO、Ti O_2;(2)富集轻稀土(LREE),亏损重稀土(HREE)及高场强元素Nb、Ta、Ti、P元素;(3)具有Eu负异常,总体显示高钾钙碱性、过铝质花岗岩和岛弧型岩浆岩特征。锆石Hf同位素特征暗示其岩浆源区为基性下地壳物质。花岗闪长玢岩脉裹挟大量侏罗纪岩浆型锆石,表明冈底斯岩基拉萨以东地区可能经历了较广泛的晚侏罗世岩浆作用。     

Petrogenesis and Tectonic Implications of the Latest Cretaceous Intrusive Rocks from the Eastern Gangdese Belt, Southeast Tibet

The latest Cretaceous magmatic activity in the eastern segment of the Lhasa terrane provides important insights for tracking the magma source and geodynamic setting of the eastern Gangdese batholith, eastward of eastern Himalayan Syntaxis. Detailed petrological, geochemical and geochronological studies of the intrusive rocks (monzodiorites and granodiorites) of the eastern Gangdese batholith are presented with monzodiorites and granodiorites giving zircon U–Pb crystallization dates of 70–66 Ma and 71–66 Ma with εHf(t) values of ?4.8 to +6.2 and ?1.9 to +5.3, respectively. These rocks are metaluminous to weakly peraluminous I-type granites showing geochemically arc-related features of enrichment in LREEs and some LILEs, e.g., Rb, Th, and U, and depletion in HREEs and some HFSEs, e.g., Nb, Ta, and Ti. The rocks are interpreted to be derived from partial melting of mantle material and juvenile crust, respectively, which are proposed to be triggered by Neo-Tethyan slab rollback during northward subduction, with both experiencing ancient crustal contamination. The studied intrusive rocks formed in a transitional geodynamic setting caused by Neo-Tethyan oceanic flat subduction to slab rollback beneath the eastern Gangdese belt during the latest Cretaceous.     

北秦岭灰池子花岗岩基成岩物质来源探讨

本文主要通过Ｎｄ，Ｓｒ和Ｏ同位素示踪研究，分析了灰池子花岗岩基的成岩物质来源，初步查明该岩体的岩浆源区由６９％的地幔物质和３１％的陆壳物质混合而成，属壳幔型花岗岩。     

西藏中拉萨地块晚侏罗世许如错花岗岩地球化学与岩石成因

西藏中部拉萨地块晚侏罗世花岗岩的岩石成因与源区性质目前尚未得到很好约束。本文报道了中部拉萨地块西段许如错岩体的寄主花岗岩和闪长质包体的锆石U-Pb年龄、元素地球化学和锆石Hf同位素成分。许如错岩体寄主花岗岩年龄为155.1±0.7Ma,闪长质包体与寄主花岗岩同期(155.7±0.7Ma)形成。寄主花岗岩属I型偏铝质-弱过铝质高钾钙碱性系列岩石,富集Rb、K等大离子亲石元素和轻稀土元素,亏损Nb、Ta、P、Ti等高场强元素,锆石εHf(t)值(-16.6~-6.6)指示其可能来源于拉萨地块古老下地壳物质的重熔作用。闪长质包体为准铝质钙碱性系列,锆石εHf(t)值(-8.9~-3.8)具有总体为负但明显高于寄主花岗岩εHf(t)值的特征,表明这些闪长质包体代表了幔源物质组成的加入。许如错晚侏罗世花岗岩可能形成于班公湖-怒江特提斯洋洋壳在中晚侏罗世向南俯冲于拉萨地块之下,引起幔源物质与中部拉萨地块古老基底重熔所产生的酸性岩浆发生岩浆混合作用形成的。     

姑婆山复式岩体的基本特征及其与成矿作用的关系

姑婆山复式岩体由晚侏罗世里松岩体、姑婆山岩体及早白垩世新路岩体组成。复式岩体为壳幔混合源成因。据岩石地球化学判断和分析,姑婆山岩体和新路岩体为含锡岩体;整个姑婆山复式岩体为含钨岩体,里松岩体和姑婆山岩体为含稀有、稀土岩体。上述矿产的形成与岩石中挥发份F、B及放射性U、T h等元素的高含量有关。     

藏南冈底斯岩基晚白垩世构造岩浆作用:以拉萨白堆复合岩体中-基性岩脉群为例

拉萨白堆复合岩体寄主为含包体的花岗闪长岩,并被一系列平行-近平行东西走向中-基性岩脉群穿插,总体形成类似"条纹码"般的构造形式。锆石U-Pb定年表明,这些基性岩脉主要形成于85~68Ma。同期中性和基性脉岩都表现出富集大离子亲石元素和LREE,亏损高场强元素,Sr同位素初始比值较低,但Nd同位素比值(εNd(t)+3.1)和锆石Hf同位素组成(εHf(t)+10.7)较高,都不具有Eu异常。与中性脉岩相比,基性脉岩具有(1)Mg O含量较高和较高的Mg#(50.6);(2)较高的Cr、Ni、Co含量;(3)较富集HREE且平坦分布。但中性脉岩Y含量较低,Sr/Y比值(38~72)较高,具有高Sr-低Y的特征;这些特征表明:这些岩浆岩的源区可能为受流体交代的岩石圈地幔。中-基性脉岩之间具有岩浆演化关系,在岩浆演化过程中以角闪石的分离结晶为主。结合文献数据,这些新数据表明冈底斯岩基的在晚白垩世(85~68Ma)经历了弧上伸展构造作用,岩浆作用持续活动,可能与新特提斯洋板片的北向斜俯冲相关。     

华北陆块南缘中生代合峪花岗岩的地球化学特征与成因

合峪花岗岩基位于华北陆块南缘外方山地区,为豫西地区燕山期最大的岩基,出露总面积达784km2,有多期侵入的特点,可划分为6个单元。主要岩石类型为黑云母二长花岗岩。LA-ICP-MS锆石U-Pb年龄资料表明,合峪花岗岩基侵位时间为148.2~135.3Ma。合峪花岗岩基的SiO2=67.16%~75.43%,Al2O3=13.29%~15.92%,MgO=0.26%~1.12%,K2O+Na2O8%,Na2O/K2O=0.88~1.43,属于高钾钙碱性系列,ACNK=0.94~1.09,为准铝质-弱过铝质花岗岩。岩体轻稀土富集、重稀土亏损((La/Yb)N=14.5×10-6~49.9×10-6,平均值27.2×10-6),Sr含量变化较大(102×10-6~848×10-6,平均290×10-6),Y、Yb含量低(Y=3.21×10-6~17.3×10-6;Yb=0.43×10-6~2.16×10-6),Eu弱亏损(δEu=0.57~0.89),反映熔体发生过长石分离结晶作用,源岩部分熔融生成熔体时残留相组合中没有或很少有长石的存在。合峪花岗岩基ISr=0.7071~0.7090,εSr(t)=40.8~65.9,εNd(t)=-16.4~-11.2,其tDM2为1.85~2.27Ga;锆石的εHf(t)主要集中于-25.39~-5.25之间,tDM2年龄介于1301~2846Ma。同位素数据显示合峪花岗岩基的源岩主要为南秦岭及扬子地块结晶基底,还混有少量熊耳群及太华群的物质。综合区域地质演化,认为合峪花岗岩基形成于秦岭造山带中生代陆内俯冲,岩石圈增厚,幔源岩浆上涌底侵导致下地壳部分熔融形成。     

藏南冈底斯岩基东段朗县杂岩早白垩世岩浆作用: 新特提斯洋二次俯冲

新特提斯洋长期俯冲消减作用在早白垩世可能经历二次俯冲启动或板片俯冲几何形态的重大转换。确定西藏南部冈底斯岩基早白垩世岩浆作用的岩石地球化学特征和作用方式是甄别上述过程的关键,对理解新特提斯洋的俯冲演化过程至关重要。本文就冈底斯岩基东段朗县杂岩中保存的各类早白垩世岩浆岩,开展了锆石U-Pb地质年代学和Hf同位素、全岩元素和同位素（Sr-Nd）组成分析。数据结果表明：1）基性岩侵位时代为早白垩世晚期（103.6~100.8Ma）,为高钾钙碱性偏铝质岩石,锆石ε_Hf（t）=+0.3~+5.7,全岩ε_Nd（t）=-0.8和-0.3,暗示其岩浆源区具有大量俯冲沉积物或流体的混入,为沉积物熔体和流体交代的地幔楔物质部分熔融的产物,经历了一定程度的角闪石分离结晶作用;2）中性岩形成于99.8~97.6Ma,略晚于基性岩,其主量元素与基性岩具有较好的线性关系,全岩ε_Nd（t）=+1.1,具有较多的地幔物质参与,为基性岩浆进一步演化形成;3）酸性岩（脉体）记录了多阶段岩浆作用（124.1~95.3Ma）,根据同位素组成不同进一步划分为两类,第一类具有较低的全岩ε_Nd（t）值（-8.3~-6.0）,其岩浆源区显示富集特征,t_DM2=1385~1586Ma,由古老地壳物质的再熔融形成;第二类的锆石ε_Hf（t）值（-2.8~+3.2）变化较大,岩脉的锆石ε_Hf（t）=+0.4~+8.1,t_DM=428~906Ma,全岩ε_Nd（t）=+0.1和+0.8,表明岩浆源区具有不均一性,为古老地壳物质被富流体地幔岩浆改造形成;和4）镁铁质包体的主量元素与寄主花岗岩具有较好的线性关系,锆石的Hf同位素组成变化较大（ε_Hf（t）=-9.3~+4.1）,变化范围可达13个ε单位,为岩浆混合成因。寄主花岗岩和角闪辉长岩分别作为酸性和基性端元,是基性岩浆与其诱发古老地壳熔融形成的花岗质岩浆经混合形成。结合冈底斯岩基早白垩世岩浆岩的研究结果,朗县杂岩在早白垩世（124~97Ma）的岩浆作用具有明显的岩浆混合现象,锆石Hf和全岩Sr-Nd同位素组成变化较大,可达13个ε单位,其岩浆源区复杂且富含流体,代表了新特提斯洋在早期（240~144Ma）经历漫长的俯冲之后,在早白垩世时期（~120Ma）俯冲带发生跃迁或俯冲角度达到临界点,导致大量俯冲沉积物和流体沿俯冲带俯冲下去,与发生部分熔融的地幔楔物质混合,底侵导致上覆古老地壳物质的再熔融,形成早白垩世复杂的岩浆岩组合,很可能是新特提斯洋二次俯冲开始的标志。

     

Isotope geochemistry and Re–Os geochronology of the Yanjiagou Mo deposit in the central North China Craton

The Yanjiagou deposit, located in the central North China Craton (NCC), is a newly found porphyry‐type Mo deposit. The Mo mineralization here is spatially associated with the Mapeng batholith. In this study, we identify four stages of ore formation in this deposit: pyrite phyllic stage (I), quartz–pyrite stage (II), quartz–pyrite–molybdenite stage (III), which is the main mineralization stage, and quartz–carbonate stage (IV). We present sulphur and lead isotope data on pyrite, and rhenium and osmium isotopes of molybdenite from the porphyry deposit and evaluate the timing and origin of ore formation. The δ³⁴S values of the pyrite range from ‐1.1‰ to −0.6‰, with an average of −0.875‰, suggesting origin from a mixture of magmatic/mantle sources and the basement rocks. The Pb isotope compositions of the pyrite show a range of 16.369 to 17.079 for ²⁰⁶Pb/²⁰⁴Pb, 15.201 to 15.355 for ²⁰⁷Pb/²⁰⁴Pb, and 36.696 to 37.380 for ²⁰⁸Pb/²⁰⁴Pb, indicating that the ore‐forming materials were derived from a mixture of lower crust (or basement rocks) and mantle. Rhenium contents in molybdenite samples from the main ore stage are between 74.73 to 254.43 ppm, with an average of 147.9 ppm, indicating a mixed crustal‐mantle source for the metal. Eight molybdenite separates yield model ages ranging from 124.17 to 130.80 Ma and a mean model age of 128.46 Ma. An isochron age of 126.7 ± 1.1 Ma (MSWD = 2.1, initial ¹⁸⁷Os = 0.0032 ± 0.0012 ppb) is computed, which reveals a close link between the Mo mineralization and the magmatism that generated the Mapeng batholith. The age is close to the zircon U–Pb age of ca. 130 Ma from the batholith reported in a recent study. The age is also consistent with the timing of mineralization in the Fuping ore cluster in the central NCC, as well as the peak time of lithosphere thinning and destruction of the NCC. We evaluate the spatio‐temporal distribution of the Mo deposits in the NCC and identify three important molybdenum provinces along the northern and southern margins of the craton formed during three distinct episodes: Middle to Late Triassic (240–220 Ma), Early Jurassic (190–175 Ma), and Late Jurassic to Early Cretaceous (150–125 Ma). The third period is considered to mark the most important metallogenic event, coinciding with the peak of lithosphere thinning and craton destruction in the NCC. Copyright © 2014 John Wiley & Sons, Ltd.