广西栗木水溪庙不对称层状伟晶岩—细晶岩岩脉的成因讨论

水溪庙不对称层状伟晶岩－细晶岩岩脉生根于黄玉钠长石花岗岩中，其底板部分多以钠质细晶岩为主，顶板部分多以钾硅质伟晶岩为主，中间部分则往往以上述二种岩性的韵律式互层为主。笔者认为，岩脉的母岩浆应该与黄玉钠长石花岗岩的母岩浆相同，是一种富含Ｆ、Ｎａ的残余花岗质熔浆。岩脉自底板至顶板在组分和结构上的规律性变化，与这种特殊熔浆在岩脉环境下的分异演化、Ｆ含量的涨落和黄玉的周期性晶出以及熔浆结晶的动力学机制有关     

滇西花岗伟晶岩

滇西壳型花岗伟晶岩，可分为七个带。其中多数为喜马拉雅期产物，主要产于剪切带内，为花岗岩浆之不混溶熔离岩浆产物。存在两个成矿系列，白云母系列以Be矿化为主，锂云母系列以Li、Nb、Ta矿化为主，同时还存在白云母一锂云母过渡系列，以Li、Sn、Nb、Ta和Be矿化为主。分异良好的富晶洞含Be花岗伟晶岩，产宝石级的绿柱石、黄玉和水晶。幔型的长岭岗伟晶黑鳞云母岩为碱性岩浆之不混溶熔离岩浆产物，以U、Th、Zr、Hf、Nb和Li矿化为主。     

英格兰西南部黄玉花岗岩的岩石成因及成矿意义

晚期富挥发分的黄玉花岗岩广泛而零星地产于英格兰西南部含Sn-Cu多金属矿化的S型黑云母花岗岩岩基中。St.Austell地区的最新观察资料查明了其野外关系，并论证了影响花岗质容矿主岩和沉积岩容矿主岩的电气石化晕的意义。黄玉花岗岩接触带通常以显示出无定向固结结构、具有石英－电气石晶洞的伟晶岩带为标志，较小的侵入黄玉花岗岩岩席在其围岩中具有对称状电气石化晕。黄玉花岗岩矿物组成复杂，除钠长石、正长石和石英外，还含原生黄玉、铁锂云母或锂云母、磷铝锂石以及各种富Nb-Ta的副矿物。在化学成分上，它们与黑云母花岗岩截然不同，特别富Li、F、P、Nb、Ta、Ga、Rb。黑云母花岗岩的晚期分异产物包括电气石花岗岩，但这部分异趋势主要涉及到B的增高，Li、F或P的变化较小我们认为，黄玉花岗岩可能不是由英格兰西南部的黑云母花岗岩浆（被属于黑云母花岗岩岩套的流纹斑岩岩脉所侵入）经结晶分异所派生，而是在钾质基性岩浆作用期间由岩基之下的熔融残留物经有限部分熔融而形成。与其它富挥发分的花岗质岩石的对比表明，英格兰西南部的黄玉花岗岩与锂伟晶岩（如Tanco)、火山玻璃(如Macusani)和其它的黄玉花岗岩（如Seward半岛）具有一些共同的重要特征。这些岩石可能代表一类基本相似的富挥发分花岗岩浆。我们认为它们的形成可能受以前曾产生过更为“正常”花岗岩浆的下地壳熔融残留物的有限部分熔融所控制，尽管目前仍有争议。     

江西凤凰岽含锡黄英岩脉特征及成因

江西会昌县岩背火山盆地密坑山含黄玉花岗岩体的北侧外接触带，产有数条含锡黄英岩脉。据野外产状、岩石结构构造等表明岩脉属岩浆成因。稀土元素研究表明，凤凰岽黄英岩ＲＥＥ含量极低，∑ＲＥＥ及配分曲线与脉侧黄玉石英化蚀变岩有着明显的区别。富氟花岗岩浆结晶晚期衍生的富Ｓｉ，Ａｌ，Ｆ含少量Ｋ，Ｎａ的残余熔浆沿断裂上侵因压力降低产生二次沸腾，使Ｋ，Ｎａ分离进入含水相，这是富Ｓｉ，Ａｌ，Ｆ；极贫Ｋ，Ｎａ的黄英岩形成的决定因素。     

川西扎乌龙地区卡吉亚二云母花岗岩、稀有金属伟晶岩的地球化学、年代学特征及二者的成矿关系

锂- 铍等稀有金属是中国乃至世界上重要的战略性关键金属矿产,美国、澳大利亚和日本等国早已将其列为禁止出口矿产名录,其战略地位非同一般。中国锂- 铍矿产资源丰富,成矿背景优越,但地表第四纪覆盖严重,且分布不均。近年甜水海- 松潘- 甘孜造山带花岗伟晶岩型锂矿资源逐步被勘探发现,引起国内外学者广泛关注。川西石渠县扎乌龙锂矿作为该造山带中部重要的花岗伟晶岩型锂矿点,厘清该矿床锂资源聚集主控因素及其稀有金属富集规律将为甜水海- 松潘- 甘孜造山带下一步战略找矿行动提供指导和重要决策依据。本文对扎乌龙地区锂辉石钠长石伟晶岩脉、白云母钠长伟晶岩脉、电气石钠长石伟晶岩脉、卡吉亚二云母花岗岩体以及岩体边部的含电气石细晶岩、十字石黑云母片岩等进行系统采样分析,利用LA- ICP- MS独居石U- Th- Pb同位素定年技术,确定扎乌龙卡吉亚二云母花岗岩形成于晚三叠世213~211 Ma,含电气石细晶岩约形成于210 Ma,白云母钠长石伟晶岩约形成于210~200 Ma,富锂伟晶岩可能在205 Ma集中产出。结合前人年代学资料,综合分析认为扎乌龙矿区由二云母花岗岩、电气石细晶岩到白云母钠长石伟晶岩和锂辉石钠长石伟晶岩形成时代逐步年轻。     

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。

     

川西地区的发现黄玉花岗岩脉

在1:20万区域地质调查过程中,我们首次在四川省西部地区,发现了黄玉花岗岩脉。该区出露地层主要是三叠纪浅变质砂岩、千枚岩、板岩。上述岩脉分布在印支期云闪正长岩,燕山期班状黑云母花岗岩,组成的复式岩体的内外接触带中,呈脉状成群产出。根据矿物组分和化学成分的不同,可分为钠长石与微斜长石两种类型。 （一） 钠长石型黄玉锂云母钠长石伟晶岩脉:呈近南北向分布于印支一燕山期复式岩体的外接触带     

广西栗木锡钨铌钽矿床岩浆液态不混溶作用及其与矿化的关系

锡钨多金属矿化多与Li-F碱长花岗岩有关,其岩浆演化晚期常发生较大规模的液态分异作用。广西栗木锡钨铌钽矿与成矿有关的岩体包括肉红色中粒碱长花岗岩以及顶部的白色细粒碱长花岗岩。矿化产于碱长花岗岩顶部附近,主要矿化类型包括花岗岩型钨锡铌钽矿化、似伟晶岩型钨矿化、长石石英脉型钨矿化和石英脉型钨锡矿化。碱长花岗岩中存在大量岩浆液态不混溶现象,包括矿囊、似伟晶岩和细晶岩等。地质地球化学研究发现,岩浆液态不混溶作用贯穿于栗木碱长花岗岩分异演化的全过程,矿囊代表岩体中富含钨锡和挥发份的岩浆,岩体顶部的似伟晶岩和细晶岩是碱长花岗岩岩浆分异的结果。在岩浆液态不混溶作用过程中,W、Sn、Nb、Ta等成矿元素以及挥发份不断富集,形成岩浆岩型、长英质脉型以及石英脉型矿化。不同类型的矿化对应岩浆液态不混溶作用的不同阶段,由此建立了栗木矿床岩浆液态不混溶的成矿演化模型。     

川西甲基卡锂矿床伟晶岩结构分带及多期岩浆成矿作用

LCT(lithium- cesium- tantalum)伟晶岩的分带有两种形式,一种是单个伟晶岩脉的内部结构分带,这种伟晶岩脉通常体积巨大,内部结构显示出成分分带的特征,单一脉体中不同结构带中可能发育不同的稀有金属矿化带,例如新疆可可托海3号伟晶岩脉;另一种分带性表现为伟晶岩和成矿系统的区域分带,通常以高分异的过铝质花岗岩为中心,围绕花岗岩数以百计的伟晶岩脉显示出不同的伟晶岩类型和矿化类型,越向外围,伟晶岩的演化程度越高。区域分带内的伟晶岩单个脉体的规模不大、内部分带性差、含矿性各不相同,甲基卡锂矿就是这一类伟晶岩矿床的典型代表。对甲基卡矿区伟晶岩的野外观察发现,含Be的9号脉、含Li的133号脉和含Nb、Ta的528号脉具有相对较好的内部结构分带性,而含Li的104号脉和308号脉的内部分带性则相对较差,推测与脉体内部多期岩浆- 热液活动有关。甲基卡矿区伟晶岩脉的相互穿插现象说明,矿区存在多期次的岩浆与成矿作用。科学钻探在JSD- 2和JSD- 3两个钻孔中均发现含锂辉石的伟晶岩脉和细晶岩脉侵入在不含矿的马颈子花岗岩中,佐证了多期岩浆与成矿事件的存在。伟晶岩中不同矿物U- Pb定年结果表明,全区伟晶岩的形成至少有两期,分别发生在213~206 Ma和199~191 Ma。依据钻孔JSD- 1的研究表明,岩浆由深至浅逐步向高分异方向演化。从下向上,花岗岩与伟晶岩同步演化,花岗岩依次出现黑云母花岗岩、含白云母的黑云母花岗岩、二云母花岗岩、白云母花岗岩和钠长石花岗岩,伟晶岩依次出现微斜长石型伟晶岩、微斜长石- 钠长石型伟晶岩、钠长石型伟晶岩和钠长石- 锂辉石型伟晶岩。根据不同深度伟晶岩的矿化特点,矿床的垂向分带大致划分如下：0~105 m的Li- Be- Nb- Ta矿化带;0~860 m的Be- Nb- Ta矿化带;0~1730 m的第一期Nb- Ta矿化带;1730~3170 m的无矿伟晶岩带;3170~3211 m的第二期Nb- Ta矿化带。     

中国花岗岩型锂矿床: 重要特征、成矿条件及形成机制

随着新能源汽车产业的快速发展和可控核聚变技术的不断革新, 锂产业已成为各国竞相发展的新兴朝阳产业, 全球锂资源争夺态势愈发激烈。中国是全球拥有花岗岩型锂矿床数量最多的国家, 目前该类型锂矿占全国锂总供应量的1/4, 进一步加强对该类型锂矿的研究和勘查对提升我国锂资源的自给能力至关重要。通过对全国40个主要花岗岩型锂矿床的时空分布、岩石序列、矿物演变、地球化学和高锂含量矿物等特征的梳理, 发现该类矿床主要形成于中生代晚侏罗世-早白垩世期间, 主要集中在华南地区尤以华南腹地的南岭地区最为密集; 近1/3的成矿岩体隐伏于地下, 出露的岩体面积普遍较小, 为0.07~5.7km²; 花岗岩体垂直方向从下至上逐渐从黑云母二长花岗岩演变为锂云母钠长石花岗岩, 其上通常发育云英岩和伟晶岩; 锂及其他稀有元素(铷铯铍铌钽钨锡)一般在强钠长石花岗岩和云英岩中高度富集; 黑云母二长花岗岩→含锂云母钠长花岗岩→云英岩, 岩浆分异程度逐步增加且逐渐从熔体过渡到熔体-流体共存体系, 全岩SiO₂含量、Nb/Ta和Zr/Hf比值、A/CNK和δEu值发生规律性变化; 多数情况下岩体伴生煌斑岩脉、辉长岩脉、辉绿岩脉、花岗斑岩脉、细晶岩脉、霏细岩脉等各类脉体。总结规律提出: (1)伟晶岩壳是较早进入岩浆房内的岩浆与上覆围岩接触而冷却固结的产物, 其构成岩浆房与外界的隔绝屏障, 使Li、F、P、H₂O等易挥发组分无法逃逸; (2)较晚进入岩浆房的岩浆经历了长时间晶粥体与残留熔体的分凝过程, 锂等稀有金属元素愈来愈富集于残余熔体中, 最终形成富锂花岗岩和云英岩; (3)各类岩脉是岩浆房底部有持续热补给从而使残留含矿熔体能够逐步抽离上升的证据: 基性岩脉来源于下伏高温地幔岩浆, 不含矿中酸性斑岩脉是岩浆房底部堆晶体重熔的产物, 含矿酸性斑岩脉和细粒岩脉来自岩浆房顶部富矿熔体-流体, 三者沿地壳裂隙快速上升至地壳浅部就位。正是由于上覆伟晶岩壳形成的封闭体系和下伏幔源岩浆提供的充足热量, 才使得岩浆房在热驱动机制下长期保持原地分异状态, 最终形成花岗岩型锂矿床。

     

Rare Earth and Rare Metal Elements Mobility and Mineralization During Magmatic and Fluid Evolution in Alkaline Granite System: Evidence from Fluid and Melt Inclusions in Baerzhe Granite,China

Baerzhe Be–Nb–Zr–REE deposit is hosted in alkaline granite (125 Ma) which intrudes in the late Jurassic Baiyingaolao Formation in the middle of the Great Hinggan Metallogenic Belt in China. The ore‐forming granite consists of three lithological facies: arfvedsonite‐bearing alkaline granite at the bottom, aegirine‐bearing albite aplite in the middle and pegmatite crust on the top. The albite aplite is the main orebody. We recognized three magmatic‐hydrothermal stages: orthomagmatic stage, late‐magmatic stage and hydrothermal stage, with the late‐magmatic stage being divided into two substages, the pegmatite substage and the aplite substage. Petrographic study on the granite, the microthermometric study on fluid inclusions and in situ laser‐ablation inductively coupled plasma mass spectrometry analysis for quartz‐hosted melt inclusions reveal the process of magmatic‐hydrothermal evolution. The finding indicates that primary magma evolved to more peralkaline by fractional crystallization, with synchronously increasing high field strength elements. An extremely high content of Zr and Nb are in the melt inclusions from last stage albite aplite (Zr, min 52 548 ppm, and Nb, min 4104 ppm). This implies that the residual magma directly formed the orebody of rare metal elements. Meanwhile, volatility was increasing during the magma evolution process and F‐bearing aqueous fluid was oversaturated at temperatures higher than 800°C. The separation of fluid from magma caused Li‐REE enrichment in F‐bearing fluid and depletion in residual melt, and led to the difference of the Y/Ho ratio between whole rock compositions and melt inclusion data. Fluid separated into a high‐salinity liquid and a low density vapor phase above 697°C, and enriched REE in the high‐salinity liquid. The oxygen isotope data shows mixing between primary magmatic‐hydrothermal fluid and meteoric water. The ubiquitous pseudo‐secondary fluid inclusions have a wide range of salinity below 462°C, which is similar to the melting temperatures of REE‐bearing daughter minerals. A model involving the mixing by meteoric water could be a mechanism for precipitation of REE minerals.     

Topaz–albite granites and rare-metal mineralization in the Limu District, Guangxi Province, southeast China

The topaz-albite granites of the Limu district are ultra-acidic, peraluminous, Li-F-Na-rich and Sn-Ta-Nb-mineralized. A distinct vertical zonation is developed in the granite stocks. There is an upward, systematic transition from leucocratic microcline-albite granite, through albite-microcline granite, topaz-albite granite, pegmatite stockscheider and layered pegmatite-aplite dikes, to K-feldspar-quartz veins and lepidolite-fluorite stringers in the country rocks. Snow-ball textures, homogeneous distribution of rock-forming and accessory minerals, disseminated mineralization, and melt inclusions in quartz, topaz, and albite are typical features indicative of their crystallization from the late stage Li-F-Na-rich and Sn-Ta-Nb-bearing residual granitic melts at a higher intrusion level. A comparison with rare-metal-bearing pegmatite, ongonite, topaz rhyolite and obsidian glass from other regions shows the worldwide existence of these specialized residual melts. Their emplacement and crystallization in a variety of geological environments result in the formation of a series of chemically similar rocks with different petrographic textures and mineral associations. The topaz-albite granites and associated mineralization in the Limu district provide a good example of highly evolved magmatic fractionation in the F-rich granite system and fluid/melt partitioning behavior of rare-metal elements during magmatic-hydrothermal evolution.     

Geochemistry of coexisting aplites and pegmatites and of their minerals from central northern Portugal

The major-, minor- and trace-elements chemistry of Hercynian granitoids and their minerals from the central area of northern Portugal indicates that the composition of the rocks and also of their minerals varies in the comagmatic sequence of granite, aplite and pegmatite. The compositional variation appears to be the result of a magmatic fractionation process and the minor and trace elements play an important role mainly in the trend aplite→pegmatite coexisting in the same vein, particularly for the minerals. A subsequent recrystallization of granites and aplites apparently did not alter the chemistry.     

茶卡北山锂辉石花岗伟晶岩锂矿化特征及成矿时限

锂是重要的战略金属矿产,锂辉石花岗伟晶岩是锂矿资源的重要来源。近来柴北缘茶卡北山地区新发现锂辉石花岗伟晶岩脉群,本文对区内锂辉石花岗伟晶岩进行了岩相学、矿物学、矿物化学、年代学研究工作,确定了锂辉石花岗伟晶岩的矿化特征及矿化年限。锂辉石花岗伟晶岩存在两期矿物组合：早期由粗粒锂辉石、粗粒钾长石、粗粒白云母、粗粒更(钠)长石、粗粒石英和铌钽铁矿等组成,属熔体结晶阶段产物;晚期由锂绿泥石、富锂云母、蠕虫状锂辉石和细粒他形石英等组成,为岩浆期后热液交代产物。根据两期矿物组合判断存在两期锂矿化,认为早期锂辉石的局部蚀变与晚期锂矿物的形成指示体系内存在锂的活化和再沉淀过程。测得与锂辉石伴生的铌钽铁矿U-Pb年龄为241.0±1.3 Ma,可代表锂辉石花岗伟晶岩熔体结晶年龄,即为早期锂成矿年代,矿床为印支期产物。     

Trace element constraints on pegmatite genesis: Tin Mountain pegmatite,Black Hills,South Dakota

The Tin Mountain pegmatite is a small, zoned granitic body that is extremely enriched in Rb and Li, but has moderate concentrations of Sr and Ba. These trace elements are modelled using granitic distribution coefficients in order to test the potentials of partial melting of metasedimentary rocks and fractionation of a less-evolved granitic melt to have produced the parental liquid to the Tin Mountain pegmatite. Batch melting of any reasonable metasedimentary source rock would likely have yielded melts that were either insufficiently enriched in Rb and Li to be the parental liquid, or that had Sr and Ba concentrations that were much higher than those estimated for the parental liquid. The modelling of simple fractional crystallization and equilibrium crystallization of a granitic melt within the compositional range of the spatially associated Harney Peak Granite gives calculated melt compositions with either lower Sr and Ba concentrations or inadequate Rb and Li enrichments, to be the parent liquid of the pegmatite. At least two variants from simple crystal-liquid fractionation models can, however, successfully account for the derivation of the parent liquid: 1) generation of a Rb-, Li-, Ba- and Sr-rich granitic melt (outside of the compositional range of the sampled portions of the Harney Peak Granite complex) by low degrees of partial melting of metasedimentary rocks found in the Black Hills, followed by moderate extents of fractional or equilibrium crystallization, 2) derivation from Harney Peak granite via a complex, multi-stage crystal-liquid fractionation process, such as progressive equilibrium crystallization.     

川西甲基卡308号伟晶岩脉年代学和地球化学特征及其地质意义

甲基卡稀有金属矿床是我国目前规模最大的伟晶岩型稀有金属矿床,308号伟晶岩脉为其中出露面积最大的伟晶岩脉,由于勘查及研究程度较低,其形成时代及成矿机制尚不明确.通过LA-MC-ICP-MS锡石U-Pb测年,首次获得产于308号伟晶岩脉中间带含锂辉石伟晶岩的年龄为210.9±4.6 Ma,表明其形成于印支晚期,为印支旋回强烈造山运动之后相对稳定阶段的产物.元素地球化学特征表明,308号伟晶岩脉中边缘带无矿细晶岩与矿床内二云母花岗岩具有相似的过铝质S型花岗岩特征,二者具有同源性,并认为其成矿机制为:花岗质岩浆在中浅成、偏还原的环境上升侵位,由细晶岩至伟晶岩演化过程中,相对分异程度升高,熔体相和富挥发分的流体相之间发生强烈碱交代作用,并在一定的结构分带中发生大规模稀有金属矿化.      

辽宁兴城新立屯地区岩浆杂岩岩石学特征、侵位顺序及地质意义

辽宁兴城新立屯地区岩浆杂岩主要由4种不同的岩石单元组成,分别为似斑状黑云母二长花岗岩,中细粒石英闪长岩,花岗细晶岩和花岗伟晶岩,前两者分布广泛且为研究区的主要岩石单元,后两者则呈脉状侵入到前两者中。应用LA-ICP-MS锆石U-Pb定年方法,测得似斑状黑云母二长花岗岩,中细粒石英闪长岩及花岗细晶岩的年龄分别为2 496±18 Ma,2 490±19 Ma,2 479±29 Ma,形成于古元古代早期。结合野外地质特征,侵位顺序由早到晚依次为:似斑状黑云母二长花岗岩,中细粒石英闪长岩,花岗细晶岩,花岗伟晶岩。岩石地球化学特征显示,新立屯地区岩浆杂岩主量元素方面具高硅(SiO2=61.38%~74.99%),富碱(Na2O+K2O=6.86%~9.41%),富Mg#(56~70)特征;A/CNK=0.91~1.18,属准铝质-过铝质岩石;微量元素方面,相对富集轻稀土元素,亏损重稀土元素,具有Eu异常(δEu=0.50~0.96);富集大离子亲石元素,亏损高场强元素;锆石Lu-Hf同位素特征εHf(t)值为-1.12~+6.13;TDM2(Hf)介于2 594~2 937 Ma,显示该套岩浆杂岩可能为地幔物质加入新生地壳再造的产物。     

新疆阿尔泰可可托海3号伟晶岩脉岩浆—热液演化和成因

新疆阿尔泰可可托海3号伟晶岩脉,由一陡倾斜的巨大岩钟和缓倾斜的板状体联合组成,总 体形态似一实心草帽。其空间分带十分明显,自外向内可依次划分出如下九个共生－结 构带 ：Ⅰ 文象、变文象伟晶岩带;Ⅱ 糖粒状钠长石带;Ⅲ 块状微斜长石带;Ⅳ 白云母-石英 带;Ⅴ 叶钠长石-锂辉石带;Ⅵ 石英-锂辉石（-叶钠长石）带;Ⅶ 白云母-薄片状钠长石 带;Ⅷ 锂云母-薄片状钠长石带;Ⅸ 石英和微斜长石核。根据伟晶岩各共生－结构带的时 空关系、矿物的多世代性和矿物中的包裹体等特征,从岩浆－热液演化的角度,探讨了伟 晶岩的成因问题,认为：Ⅰ、Ⅲ带和部分Ⅱ、Ⅳ带主要是富水但水不饱和的伟晶岩浆 直接结晶的产物;Ⅴ、Ⅵ、Ⅶ带是在晶体相、熔体相和流体相三相并存的条件下,即岩浆— 热液过渡阶段结晶形成的;Ⅸ带是在热液早阶段从高温富硅酸盐溶质的超临界流体中结晶出 来 的;Ⅷ带和部分Ⅱ、Ⅳ带则是热液交代的产物。但交代流体不是从深部外来,而是从伟 晶岩浆体系本身在分异演化过程中发生液相分离的结果。     

The Cretaceous Ofuku Pluton and Its Relation to Mineralization in the Western Akiyoshi Plateau,Yamaguchi Prefecture,Japan

The relationship between the magmatism of the Cretaceous Ofuku pluton and mineralization in and around the Akiyoshi Plateau, Yamaguchi Prefecture, Japan was investigated using a combination of field observation, petrographic and geochemical analyses, K–Ar geochronology, and fluid inclusion data. The Ofuku pluton has a surface area of 1.5 × 1.0 km, and was intruded into the Paleozoic accretionary complexes of the Akiyoshi Limestone, Ota Group and Tsunemori Formation in the western part of the Akiyoshi Plateau. The pluton belongs to the ilmenite‐series and is zoned, consisting mainly of early tonalite and granodiorite that share a gradational contact, and later granite and aplite that intruded the tonalite and granodiorite. Harker diagrams show that the Ofuku pluton has intermediate to silicic compositions ranging from 60.4 to 77.9 wt.% SiO₂, but a compositional gap exists between 70.5 to 73.4 wt.% SiO₂ (anhydrous basis). Modal and chemical variations indicate that the assumed parental magma is tonalitic. Quantitative models of fractional crystallization based on mass balance calculations and the Rayleigh fractionation model using major and trace element data for all crystalline phases indicate that magmatic fractionation was controlled mainly by crystal fractionation of plagioclase, hornblende, clinopyroxene and orthopyroxene at the early stage, and quartz, plagioclase, biotite, hornblende, apatite, ilmenite and zircon at the later stage. The residual melt extracted from the granodiorite mush was subsequently intruded into the northern and western parts of the Ofuku pluton as melt lens to form the granite and aplite. The age of the pluton was estimated at 99–97 Ma and 101–98 Ma based on K–Ar dating of hornblende and biotite, respectively. Both ages are consistent within analytical error, indicating that the Ofuku pluton and the associated Yamato mine belong to the Tungsten Province of the San‐yo Belt, which is genetically related to the ilmenite‐series granitoids of the Kanmon to Shunan stages. The aplite contains Cl‐rich apatite and REE‐rich monazite‐(Ce), allanite‐(Ce), xenotime and bastnäsite‐(Ce), indicating that the residual melt was rich in halogens and REEs. The tonalite–granodiorite of the Ofuku pluton contains many three‐phase fluid inclusions, along with daughter minerals such as NaCl and KCl, and vapor/liquid (V/L) volume ratios range from 0.2 to 0.9, suggesting that the fluid was boiling. In contrast, the granite and aplite contain low salinity two‐phase inclusions with low V/L ratios. The granodiorite occupies a large part of the pluton, and the inclusions with various V/L ratios with chloride daughter minerals suggest the boiling fluids might be related to the mineralization. This fluid could have carried base metals such as Cu and Zn, forming Cu ore deposits in and around the Ofuku pluton. The occurrence and composition of fluid inclusions in the igneous rocks from the Akiyoshi Plateau are directly linked to Cu mineralization in the area, demonstrating that fluid inclusions are useful indicators of mineralization.