Late Cambrian to Early Silurian Granitic Rocks of the Gemuri Area,Central Qiangtang,North Tibet: New Constraints on the Tectonic Evolution of the Northern Margin of Gondwana

The Paleozoic tectonic framework and paleo–plate configuration of the northern margin of Gondwana remain controversial. The South Qiangtang terrane is located along the northern margin of Gondwana and records key processes in the formation and evolution of this supercontinent. Here, we present new field, petrological, zircon U-Pb geochronological, and Lu-Hf isotopic data for granitic rocks of the Gemuri pluton, all of which provide new insights into the evolution of the northern margin of Gondwa...     

喜马拉雅东段库曲岩体锂、铍和铌钽稀有金属矿物研究及指示意义

稀有金属矿物记录了花岗伟晶岩成岩成矿的重要信息。喜马拉雅是全球著名的淡色花岗岩带,库曲岩体位于喜马拉雅东段的特提斯喜马拉雅岩系中。本文调查了库曲岩体的二云母花岗岩、白云母花岗岩、电气石花岗岩和花岗伟晶岩,其中,花岗伟晶岩涉及花岗岩的伟晶岩相和独立伟晶岩脉。库曲岩体产出的稀有金属矿物包括锂辉石、锂绿泥石、绿柱石、铌铁矿-钽铁矿、钇铀钽烧绿石和细晶石,它们主要赋存于似文象伟晶岩、石英-钠长石-白云母伟晶岩、块体长石-钠质细晶岩、块体长石-电气石钠质细晶岩、锂辉石-块体长石-细晶岩、白云母花岗岩的伟晶岩相以及电气石花岗岩内。显微镜观察、电子探针和LA-ICP-MS测试结果显示锂辉石具有四种产状,包括粗粒锂辉石自形-半自形晶、细粒锂辉石-石英镶嵌晶、中细粒锂辉石-钾长石-钠长石-云母镶嵌晶以及发育锂绿泥石的粗粒锂辉石,揭示了其形成时复杂的熔流体动荡结晶环境。绿柱石背散射电子图像（BSE）下呈均一结构和不均一结构（蚀变边、不规则分带和补丁分带）,元素替代机制包括通道-八面体替代、通道-四面体替代以及通道中碱金属阳离子间的置换。铌铁矿族矿物包括原生、蚀变边和不规则分带结构,部分被钇铀钽烧绿石和细晶石交代。与原生铌铁矿相比,蚀变边和不规则分带铌铁矿族矿物总体上富钽贫锰,显示了结晶分异、过冷却引起的过饱和以及流体作用。根据稀有金属矿物揭示的成因信息,独立伟晶岩脉（似文象伟晶岩）、白云母花岗岩的伟晶岩相和电气石花岗岩在岩浆分异程度、经历的演化过程、以及流体活动方面存在差异,很可能是不同期次岩浆活动的产物。库曲岩体绿柱石的Rb和Zn含量、以及铌铁矿族矿物的Sc₂O₃、SiO₂和PbO含量,与已有指示标志存在相关性,作为潜在指示标志仍需开展更多的研究工作。综合含锂辉石伟晶岩的产出、岩浆分异演化程度、多期花岗质岩浆活动、复杂的流体作用以及所属锂丰度高值区等因素,库曲岩体是喜马拉雅东段找锂的有利地段。

     

个旧老卡岩体接触-凹陷带构造控矿特征研究

个旧老卡岩体接触-凹陷带是个旧矿集区最重要的锡铜多金属成矿构造带,带内锡铜矿体的成生与凹陷带构造密切相关,受构造、岩性和岩浆活动联合控制,凹陷带的形态、产状、规模的变化直接影响矿体的形态、产状、规模.凹陷带构造是一个有利成矿的构造部位,并配之有其他控矿因素,最终在燕山晚期含矿岩浆气液作用下形成富厚矿体.     

Fluid Characteristics and Evolution of the Zhawulong Granitic Pegmatite Lithium Deposit in the Ganzi‐Songpan Region,Southwestern China

The Zhawulong granitic pegmatite lithium deposit is located in the Ganzi-Songpan orogenic belt. Fluid inclusions in spodumene and coexisting quartz were studied to understand the cooling path and evolution of fluid within albite–spodumene pegmatite. There are three distinguishable types of fluid inclusions: crystal-rich, CO2–NaCl–H2O, and NaCl–H2O. At more than 500°C and 350~480 MPa, crystal-rich fluid inclusions were captured during the pegmatitic magma-hydrothermal transition stage, characterized by a dense hydrous alkali borosilicate fluid with a carbonate component. Between 412°C and 278°C, CO2–NaCl–H2Ofluid inclusions developed in spodumene (I) and quartz (II) with a low salinity (3.3–11.9 wt%NaCl equivalent) and a high volatile content, which represent the boundary between the transition stage and the hydrothermal stage. The subsequentNaCl–H2Ofluid inclusions from the hydrothermal stage, between 189°C and 302°C, have a low salinity (1.1–13.9 wt%NaCl equivalent). The various types of fluid inclusions reveal the P–T conditions of pegmatite formation, which marks the transition process from magmatic to hydrothermal. The ore-forming fluids from the Zhawulong deposit have many of the same characteristics as those from the Jiajika lithium deposit. The ore-forming fluid provided not only materials for crystallization of rare metal minerals, such as spodumene and beryl, but also the ideal conditions forthe growth of ore minerals. Therefore, this area has favorable conditions for lithium enrichment and excellent prospecting potential.     

A Sequence of Pan-African and Hercynian Events Recorded in Zircons from an Orthogneiss from the Hercynian Belt of Western Central Iberia--an Ion Microprobe U-Pb Study

Sensitive high-resolution ion microprobe U–Pb dating showsthat a biotite orthogneiss from the Hercynian belt of westerncentral Iberia contains 1000–300 Ma zircon. Older, 1000–570Ma ages within this range represent inherited, detrital materialamong which four age components may be recognized:     

中国东南部晚中生代花岗质火山-侵入杂岩特征与成因

晚中生代期间,中国东南部岩浆活动十分强烈。 由内陆向沿海,花岗岩、火山岩的时代越来越新。花岗岩 与酸性、中酸性火山岩在成因上存在密切联系。在时间、空间和成岩物质来源一致的条件下 ,花岗岩可视为流纹岩、英安岩所构成的中心式火山机构的“根”,形成所谓的花岗质火山-侵入杂岩。中国东南部的花岗质火山-侵入杂岩可以区分为同熔型、陆壳重熔型和A 型三类,它们具有不同的构造环境、形成机制和物质来源。同熔型火山-侵入杂岩主要分布 于沿海,陆壳重熔型火山-侵入杂岩一般分布于内陆,而 A型花岗质火山-侵入杂岩主要受浙闽沿海长乐-南澳断裂带控制。 以桐庐和相山两个典型杂岩体为代表剖析了花岗质火山-侵入杂岩 体的时、空、源一致性,所揭示的规律对于认识整个中国东南部晚中生代花岗质火山-侵入 杂岩的成因具有普遍意义。     

闽西南玮埔岩体和赣南菖蒲混合岩锆石La ICPMS U-Pb年代学

闽西玮埔岩体和赣南菖蒲混合岩位于武夷山构造带南部地区。对NNE向展布的闽西玮埔岩体两个样品进行了锆石LaICPMS U-Pb 测年,获得的年龄为447.1±4.7Ma和440.8±3.4Ma,证明这个岩体不是原来认为的印支期花岗岩,而属于加里东岩体。赣南菖蒲混合岩发育于罗浮岩体的北侧,早期将罗浮岩体归于燕山早期岩体。对混合岩进行的锆石LaICPMS U-Pb 测年,获得的年龄为445.9±3.8Ma,确定这个岩体为加里东期。这些新的高精度年龄学数据为武夷山加里东构造运动时限和性质提供了精确约束。     

TTG岩套的成因及其形成环境

TTG岩套是一类包含了三种岩性的岩石组合,即英云闪长岩(tonalite)—奥长花岗岩(trondhjemite)—花岗闪长岩(granodiorite)。TTG岩套的规模在太古宙最大,是早期陆壳的主体且在各地质历史时期均有发育。该岩石组合是岩石学定名,多数样品的地球化学特征相似:富Na,高Al2O3(平均15%),低Mg、Ni、Cr,富集LREE、亏损HREE、高Sr、低Y、低Yb且无明显的负Eu异常。其微量元素特征与Adakite(高锶低钇中酸性岩,"埃达克岩")类似。目前多数学者认同其为变玄武质岩石部分熔融后的熔体,主要争论在于其源岩的变质程度。笔者认为TTG岩套的源区不应局限于某个变质相,而是涵盖了较大的P—T范围。对于其形成环境的探讨,笔者认为应该以地球演化不同时期的地球动力学背景为前提,盲目地"将今论古"是不合理的。本文在总结前人研究成果的基础上提出3.8Ga之前的TTG岩套可能是在板块构造未启动的非俯冲条件下形成的;3.8~1.9Ga的TTG岩套产生在发育俯冲式板块构造且板块构造具有间歇式特点的背景下,此时可能既存在非俯冲环境下产出的TTG岩套也存在俯冲环境下产出的TTG岩套,而且其产出应该具有幕式特征;古元古代之后的TTG岩套可能无一例外均是俯冲板片熔融的产物。     

钨、锡流-熔分配实验结果及其矿床成因意义

本文用实验确定了钨、锡在成分不同的花岗质熔体相与共存水热流体相的流-熔分配系数(D_(Me)~(V/L))及其与介质溶液(NaF,KF,HF,NaCl等水溶液)摩尔浓度间的函数关系。实验结果表明,钨、锡的分配行为明显不同。在相同条件下,随体系的不同,D_W~(V/L)比D_(Sn)~(V/L)大几倍至二十倍。钠和钾对钨、锡的流-熔分配行为的影响基本相同,而氟和氯对钨、锡的分配行为的影响相差甚远,花岗质熔体的主成分对D_W~(V/L)和D_(Sn)~(V/L)有复杂的影响。利用这些结果探讨与花岗岩有关的钨、锡矿床的成矿机理,得出了一些与前人不同的新认识。     

Rapid cooling and geospeedometry of granitic rocks exhumation within a volcanic arc: A case study from the Central Slovakian Neovolcanic Field (Western Carpathians)

U–Pb Sensitive High‐Resolution Ion MicroProbe (SHRIMP) dating of zircon in combination with (U–Th)/He dating of zircon and apatite is applied to constrain the emplacement and exhumation history of the youngest granitic rocks in the Western Carpathians collected in the Central Slovakian Neovolcanic Field. Two samples of diorite from the locality Banky, and granodiorite from Banská Hodru?a yield the U–Pb zircon concordia ages of 15.21 ±0.19 Ma and 12.92 ±0.27 Ma, respectively, recording the time of zircon crystallization and the intrusions’ emplacement. Zircon (U–Th)/He ages of 14.70 ±0.94 (Banky) and 12.65 ±0.61 Ma (Banská Hodru?a), and apatite (U–Th)/He ages of 14.45 ±0.70 Ma (diorite) and 12.26 ±0.77 Ma (granodiorite) are less than 1 Myr younger than the corresponding zircon U–Pb ages. For both diorite and granodiorite rocks their chronological data thus document a simple cooling process from magmatic crystallization/solidification temperatures to near‐surface temperatures in the Middle Miocene, without subsequent reheating. Geospeedometry data suggest for rapid cooling at an average rate of 678 ±158 °C/Myr, and the exhumation rate of 5 mm/year corresponding to active tectonic‐forced exhumation. The quick cooling is interpreted to record the exhumation of the studied granitic rocks complex that closely followed its emplacement, and was likely accompanied by a drop in the paleo‐geothermal gradient due to cessation of volcanic activity in the area.