Geochemistry of K‐feldspar and Muscovite in Rare‐element Pegmatites and Granites from the Totoral Pegmatite Field,San Luis,Argentina

The geochemistry of K‐feldspar for K, P, Sr, Ba, Rb, Cs, Ga, and of muscovite for the same elements plus Nb and Ta, was used for proving the parental relationships of S‐type granites and LCT (Li, Cs, Ta) rare‐element pegmatites in the southernmost pegmatitic field of the Pampean pegmatite province in Argentina. The variation of K/Rb‐Cs, K/Cs‐Rb, K/Rb‐Rb/Sr, K/Rb‐Ba in K‐feldspar from the granites and pegmatites show that they form an association with the evolutional sequence: granites → barren‐ to transitional pegmatites → beryl type, beryl‐columbite‐phosphate pegmatites → complex type of spodumene subtype pegmatites → albite‐spodumene type → albite type pegmatites. This sequence reflects the regional distribution of the different magmatic units. The Ta‐Cs diagram for muscovite reveals that none of the studied pegmatites exceed the threshold established in previous studies for being considered with important tantalum oxide mineralization. The granites and pegmatites constitute a rare‐element pegmatitic field in which different magmatic units form a continuous fractionation trend, extended from the less evolved granitic facies to the most geochemically specialized pegmatites     

Geochemistry of lepidolitic granitoids from the Mungutiyn Tsagaan Durulj occurrence (central Mongolia)

We studied the geologic position, geodynamic setting, petrology, and geochemistry of veined lepidolitic granitoids from the Mungutiyn Tsagaan Durulj (MTD) occurrence (central Mongolia), found within the area of Mesozoic intraplate rare-metal magmatism. It has been established that their trace-element enrichment resulted from the intense effect of fluids rich in F, K, Li, Rb, Cs, Sn, Be, and W, which arrived from a deep magma chamber of rare-metal granitic melts, on leucogranites with originally weak rare-metal mineralization. Very high contents of F, rare alkali metals, Sn, Be, and W, characteristic of MTD granitoids, are close only to those in greisens of rare-metal granites and topaz-lepidolite-albitic pegmatites. The difference from the greisens in each case might be due to the features of the original rocks. The difference between the greisenized MTD leucogranites and the topaz-lepidolite-albitic pegmatites is more radical: Along with evident petrographic distinctions, it includes an evolution trend toward the albite norm decrease, not typical of Li–F igneous rocks; rock shearing and gneissosity, which must have contributed to their chemical transformation according to this trend; and stably lower contents of Nb and Ta (trace elements which usually accumulate during crystallization fractionation of F–Li granitic melts and are poorly soluble in magmatic fluids). The greisenized MTD granitoids are not only high-grade rare-metal ores of Li, Rb, F, and Sn but are also regarded as an indicator of a deep concealed pluton of rare-metal granites.     

Geochemistry of granulite‐facies granitic rocks from Battye Glacier,northern Prince Charles Mountains,East Antarctica

Proterozoic basement outcrops in the vicinity of Battye Glacier, northern Prince Charles Mountains, are dominated by granulites and gneisses derived from felsic (granitoid) intrusive igneous rocks, and by pegmatites. Felsic orthopyroxene granulites, garnet leucogneisses and garnet pegmatites have major and trace element compositions of highly felsic, but not strongly fractionated, granites. The garnet leucogneisses and garnet pegmatites have S‐type characteristics, whereas the felsic granulites are probably I‐type, although their high Zr+Nb+Y+Ce abundances suggest possible A‐type affinities. Intermediate orthopyroxene ± clinopyroxene granulites mostly resemble I‐type quartz diorites, except for a small subgroup of samples (characterised by low Na₂O and K₂O, and high MgO, Ni, Cr and HREE) of uncertain affinities and significance. Element ratios involving LILE (e.g. K/Rb, Rb/Ba, Rb/Sr, K/La, La/Th) closely match those typical of the inferred granitoid protoliths, suggesting that these rocks have experienced relatively little LILE depletion (except possibly for U) during regional metamorphism. It is therefore inferred that metamorphism was probably broadly isochemical. Because the felsic and intermediate granulites and garnet leucogneisses are Sr‐depleted, Y‐undepleted and mostly have negative Eu anomalies they are inferred to be the products of partial melting of felsic crustal sources leaving plagioclase‐bearing residua. Plagioclase fractionation during crystallisation could also account for these characteristics, but K/Rb, Rb/Ba and Rb/Sr ratios in these rocks are not consistent with strong fractionation of feldspar. Garnet pegmatites differ chemically from garnet leucogneisses mainly in their lower Fe, Ti, Nb, Zn, Zr, Th and REE abundances and positive Eu anomalies, related to lower garnet, ilmenite and zircon contents in the garnet pegmatites. A genetic link between these two rock types, probably involving fractionation of these minerals during partial melting or crystallisation, is inferred. Incompatible‐element abundances suggest that generation of the Battye Glacier granitic magmas from felsic crust might have occurred in a mature continental magmatic arc possibly well removed from an active subduction trench or, perhaps, in an intracontinental setting.     

铌钽矿研究进展和攀西地区铌钽矿成因初探

铌钽矿主要产出类型包括伟晶岩型、富Li-F花岗岩型、碱性侵入岩型、碳酸岩型及冲积砂矿型。前2种类型以钽为主,后3种则以铌占主导。铌和钽大多以铌钽独立矿物(铌铁矿、钽铁矿、细晶石、烧绿石等)呈浸染状分布于含矿岩石中,也有部分以类质同象的形式分布于云母、榍石、霓石、钛铁矿等矿物中。关于铌钽矿的富集机制,一些学者认为可由富F-Na和稀有金属(铌、钽等)的花岗质熔体经结晶分异作用形成;另一些学者则根据铌钽矿化与岩石的钠长石化、锂云母化等紧密共生的特点,认为铌钽的富集是岩浆期后流体交代早期形成的花岗岩所致。攀西(攀枝花-西昌)地区的铌钽矿床(化)基本上都是沿着断裂带分布,矿体赋存于印支期碱性岩脉(碱性正长伟晶岩)中,有少数存在于碱性花岗岩中,与区域上邻近的正长岩体及花岗岩体关系密切。其矿石矿物主要为烧绿石、褐钇铌矿等。初步推断,攀西地区的铌钽矿与二叠纪地幔柱活动有关。碱性的正长岩体及花岗岩体与广泛分布的峨眉山玄武岩、辉长岩均是地幔柱岩浆活动的产物,长英质岩体(包括正长岩体和花岗岩体)是富铌钽岩石的母岩体。碱性伟晶岩脉(如炉库和白草地区)是碱性岩浆逐步演化的产物,含矿的碱性花岗岩是花岗质岩浆分异演化的结果。此外,在该地区的铌钽矿床中,铌钽矿物几乎都富集在钠长石化发育的地段,说明后期的热液交代对铌钽的富集也起到了一定作用。因此,攀西地区铌钽的富集是岩浆结晶分异和岩浆期后热液交代共同作用的结果。     

Mineralogy,geochemistry, and genesis of co-genetic granite-pegmatite-hosted rare metal and rare earth deposits of the Kawadgaon area,Bastar craton,Central India

Co-genetic pegmatites associated with the granite of the Kawadgaon area in the Bastar craton, Central India, contain a wide range of ore minerals of Nb, Ta, Be, Sn, Zr, Ti, and REE, including columbite-tantalite, ixiolite, pseudo-ixiolite, wodginite, tapiolite, microlite, fersmite, euxenite, aeschynite, beryl, cassiterite, monazite, xenotime, zircon, ilmenite, triplite, and magnetite. There is a distinct vertical zonation between the rare metal and tin pegmatites in apical parts of the host granite. Geochemically, these are LCT-S type, beryl-columbite-phosphate pegmatites that have notably high contents of SiO₂ (av. 73.80%), Rb (av. 381 ppm), and Nb (av. 132 ppm). The investigated granites probably were derived from the melting of older crustal rocks, as indicated by a high initial ⁸⁷Sr/⁸⁶Sr isotopic ratio, and the major-element geochemistry of the granites and pegmatites. Plots of mol. CaO/(MgO+FeO^t) vs. mol. Al₂O₃/(MgO+FeO^t) suggest that the source rock was pelitic metasediments. Based on the available data, it is postulated that the derivation of pegmatites from the parent granite occurred shortly after granite emplacement in the late Archaean-early Proterozoic (~2500 Ma). The K/Rb, Ba/Rb, and Rb/Sr ratios of the felsic bodies reveal that a substantial part of the granite formed from evolved melts, and further fractionation produced the co-genetic pegmatites and associated rare metal and rare earth deposits.     

藏南拉隆穹窿的厘定及其稀有多金属成矿作用新发现

拉隆穹窿位于特提斯喜马拉雅构造带东南缘,与错那洞穹窿、库局穹窿构成平行于拉轨岗日穹窿带的另一条重要穹窿带.穹窿被上下拆离断层分割为核部单元、过渡带和盖层.核部单元主要由花岗片麻岩、淡色花岗岩和伟晶岩组成,花岗片麻岩锆石U-Pb年龄为474.3±5.5 Ma,淡色花岗岩主要包括二云母花岗岩和黑云母花岗岩两类;过渡带由石榴石片岩、十字石片岩、红柱石片岩、蓝晶石片岩,以及大理岩、矽卡岩化大理岩、矽卡岩等组成,由内向外显示出巴罗型变质分带特征;盖层由中生界浅变质碎屑沉积岩组成.拉隆穹窿中新发现有3类稀有多金属矿化作用,第1类为伟晶岩型铍矿化,主要富铍矿物为绿柱石,伟晶岩的独居石U-Pb年龄为23.19±0.12 Ma;第2类为矽卡岩型铍、钨、铌、钽稀有多金属矿化,矽卡岩型稀有多金属矿化产于白云母花岗岩与大理岩接触带,白云母花岗岩独居石U-Pb年龄为23.23±0.27 Ma;第3类为受构造控制的热液铜铅锌银矿化.拉隆稀有多金属矿化显示出以淡色花岗岩为核心向外的Be、Be-W-Nb-Ta、Cu-Pb-Zn-Ag矿化分带特征.拉隆穹窿的厘定表明特提斯－喜马拉雅成矿带存在一条“双穹窿”构造带,拉隆穹窿稀有多金属成矿作用的发现,进一步证实特提斯喜马拉雅成矿带具有巨量稀有金属找矿潜力,有望成为我国继华南和新疆阿尔泰之后第3条稀有金属成矿带.      

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。     

Distribution and petrogenetic behaviour of trace elements in granitic pegmatite quartz from South Norway

The present study documents that the trace-element distribution in granitic quartz is highly sensitive to CAFC processes in granitic melts. Igneous quartz efficiently records both the origin and the evolution of the granitic pegmatites. Aluminium, P, Li, Ti, Ge and Na in that order of abundance, comprises >95% of the trace elements. Most samples feature >1 ppm of any of these elements. The remnant 5% includes K, Fe, Be, B, Ba and Sr whereas the other elements are present at concentrations lower than the detection limit. Potassium, Fe, Be and Ti are relatively compatible hence obtain the highest concentrations in early formed quartz. Phosphorous, Ge, Li and Al are relatively incompatible and generally obtain the highest concentrations in quartz that formed at lower temperatures from more evolved granitic melts. The Ge/Ti, the Ge/Be, the P/Ge and the P/Be ratios of quartz are strongly sensitive to the origin and evolution of the granitic melts and similarly the Rb/Sr and the Rb/K ratios of K-feldspars may be utilised in petrogenetic interpretations. However, the quartz trace element ratios are better at distinguishing similarities and differences in the origin and evolution of granitic melts. After evaluating the different trace element ratios, the Ge/Ti ratio appears to be most robust during subsolidus processes in the igneous systems, hence probably should be the preferred ratio for analysing and understanding petrogenetic processes in granitic igneous rocks.Editorial responsibility: J. Hoefs     

新疆阿尔泰造山带中伟晶岩型稀有金属矿床成矿 规律、找矿模型及其找矿方向

文章对阿尔泰造山带中的主要伟晶岩类型、时空分布特征、形成物源以及稀有金属矿化类型、形成条件(包括温度、压力、侵位深度)、可能控制因素等进行了归纳和总结,进而提出了阿尔泰伟晶岩成因模式、稀有金属矿化机制、伟晶岩型稀有金属矿床找矿模型及其找矿方向。阿尔泰稀有金属伟晶岩显示2个期次(同造山和后造山)和4个阶段(泥盆纪—早石炭世、二叠纪、三叠纪、早侏罗世)的成岩成矿特征。其中,以后造山阶段的三叠纪伟晶岩成岩及其Be、Li成矿作用最为显著。不同期次和阶段的伟晶岩显示规律的时空分布特征,稀有金属伟晶岩的成岩成矿明显受"构造-变质-物源-岩浆"的控制,而伟晶岩与周边花岗岩存在时代或物源上的解耦,表明阿尔泰伟晶岩不是由花岗质岩浆分异演化晚期的残余岩浆固结形成,由此提出阿尔泰不同时代伟晶岩的成因模式,即造山过程中加厚的不成熟地壳物质在伸展减压背景下发生小比例部分熔融(深熔)形成独立伟晶岩。通过对形成伟晶岩初始岩浆中磷含量、伟晶岩分异演化程度的评价以及基于围岩蚀变过程中全岩及蚀变矿物电气石中稀有金属Li、Rb、Cs含量特征,建立了阿尔泰伟晶岩型稀有金属矿床找矿模型、地质-地球化学找矿指标体系,并提出不同尺度的找矿方向。     

中国内生稀有稀土矿床的时空分布

内生稀有稀土矿床在我国广泛分布，矿床的形成时代从太古宙到喜马拉雅期。矿床类型主要有碱性岩型、花岗岩型及花岗伟晶岩型三大类型。碱性岩型矿床的形成时代从元古宙到喜马拉雅期，主要集中在中元古代及华力西－印支期。这类矿床多分布在地台稳定区的边缘，常沿深断裂或裂谷带延展方向呈群分布。花岗岩型矿床绝大多数形成于燕山期，主要见于南岭及其邻区。成矿花岗岩常是花岗岩复式岩体的晚期侵入体，沿大岩体周边或隐伏岩体上方作定向分布。花岗伟晶岩型矿床主要形成于华力西－印支期，大多数分布在地槽褶皱带内。褶皱带内的复背斜及更次一级背斜的轴部及倾没端常是矿化伟晶岩的赋存场所。以攀西裂谷带内的牦牛坪、茨达等碱性岩型矿床，赣南加里东褶皱带内的西华山、荡坪等花岗岩型矿床，闽西北加里东褶皱带内的溪源头、西坑等花岗伟晶岩型矿床为例具体地描述了三类矿床在空间上的定向分布。西部地区是找寻大型内生稀有稀土矿床极有潜力的地区。     

The Greer Lake leucogranite, Manitoba, and the origin of lepidolite-subtype granitic pegmatites

The Archean Greer Lake leucogranite intruded metabasalts of the Bird River Greenstone Belt in the southwestern part of the Superior Province of southeastern Manitoba. The considerably evolved, multiphase, peraluminous, B-, P-, and S-poor leucogranite (K/Rb 132 to 24) was probably generated by fault-friction-assisted anatexis of dominantly metatonalitic rocks and subsequent differentiation. The leucogranite produced interior, transitional, non-crosscutting pods of barren, beryl-columbite- and lepidolite-subtype pegmatites that solidified from local segregations of highly fractionated residual melt. Steep fractionation gradients characterize the granite-to-pegmatite transition, most conspicuously so in the case of the most evolved, Li, Rb, Cs, Be, Mn, Sn, Nb-Ta, F-rich, lepidolite-subtype pod AC #3 (with K/Rb ≥ 16 and Cs 330 ppmwt in accessory K-feldspar, ≥2.5 and ≤11,200 ppmwt, respectively, in lepidolite, Cs ≤28,000 ppmwt in beryl, and Ta/(Ta+Nb) at. ≤ 0.95 in manganotantalite). The Greer Lake example documents beyond any doubt the igneous derivation of lepidolite-subtype pegmatites from a plutonic parent. Most cases of generally very scarce lepidolite-subtype pegmatites obscure this relationship, as the volatile-rich, highly fluid melts stable to relatively low temperatures commonly migrate to great distances from their plutonic sources.     

Geochemistry of granitic aplite-pegmatite dykes and sills and their minerals from the Gravanho-Gouveia area in Central Portugal

Two distinct series of Variscan granitic rocks have been distinguished in the Gravanho-Gouveia area of Portugal, based on field work, variation diagrams for major and trace elements, rare earth patterns and δ¹⁸O versus total FeO diagram of rocks, anorthite content of plagioclase, BaO and P₂O₅ contents of feldspars and Al^VI versus Fe²⁺ diagram for magmatic muscovite. One series consists of a late-orogenic porphyritic biotite > muscovite granite (G1), less evolved beryl-columbite pegmatites and more evolved beryl-columbite pegmatites showing gradational contacts. The other series consists of post-orogenic porphyritic muscovite > biotite granodiorite to granite (G2), slightly porphyritic muscovite > biotite granite (G3) and lepidolite pegmatites. In each series, pegmatites are derived from the parent granite magma by fractional crystallization of quartz, plagioclase, K-feldspar, biotite and ilmenite. Some metasomatic effects occur like muscovite replacing feldspars, chlorite in pegmatites of the first series and a late muscovite in pegmatites of the second series, probably due to hydrothermal fluids. The lepidolite pegmatites contain cassiterite and two generations of rutile. The first magmatic generation consists of homogeneous crystals and the second generation occurs as heterogeneous zoned crystals derived from hydrothermal fluids. The beryl-columbite pegmatites and lepidolite pegmatites also contain the first magmatic generation and the late hydrothermal generation of zoned columbite-group minerals. More evolved beryl-columbite pegmatites were converted into episyenite by intense hydrothermal alteration and regional circulation of fluids in the granitic rocks.     

Shigar valley gemstones,their chemical composition and origin,Skardu, Gilgit-Baltistan,Pakistan

A variety of gemstones is being mined in the Shigar valley, Skardu, Pakistan. These include beryl (goshenite and aquamarine), tourmaline (schorl), garnet (almandine–spessartine), apatite, topaz, fluorite, zoisite, clinozoisite, and axinite, mostly occurring in complex or zoned pegmatites and metamorphic rocks. These have been analyzed using electron probe micro-analyzer and X-ray diffractometer. The mineral chemistry of each gemstone is similar to its respective typical gemstone variety with homogenous chemical composition. Field and chemical characteristics suggest that beryl, tourmaline, garnet, apatite, topaz, and fluorite are occurring in zoned pegmatites which are largely formed by magmatic hydrothermal fluids in the cavities and vugs within the intermediate zone. However, zoisite, clinozoisite, and axinite may have a metamorphic and/or metasomatic origin.     

Mineralization of pegmatites in parts of the Oban Massif, Southeastern Nigeria： A preliminary analysis

The Oban Basement Massif of southeastern Nigeria is composed of metamorphosed rocks including phyllites, schists, gneisses and amphibolites cut by pegmatitic dykes of varying length and thickness, which intruded the metamorphic rocks. Preliminary geochemical study and analysis of these pegmatites from western Oban Massif at Uyanga, Akwa Ibami, Iwuru I, Iwuru Ⅱ and Igbofia showed that the pegmatites are highly albitized. This is incon-sistent with earlier postulations that the pegmatites in this part of Nige...     

The spodumene deposit at “Weinebene”, Koralpe,Austria

The Weinebene spodumene deposit is located in Carinthia, about 270 km southwest of Vienna. It is hosted by the medium- to high-grade metamorphic rocks of the Koralpe. The spodumene-bearing pegmatites form unzoned, dikelike bodies in eclogitic amphibolites and kyanite-bearing micaschists with concordant foliations. Their lateorogenic emplacement is probably of Variscan age. A younger, probably Alpine metamorphic event affected the pegmatites; it caused extensive recrystallization of the micaschist-hosted pegmatites, but had only a minor impact on the amphibolite-hosted ones. The spodumene-bearing pegmatites have been traced over a length of 1.5 km along strike and to about 450 m down dip. Their average thickness is 2 m, with a maximum of 5.5 m. Emplacement of the pegmatites caused an alteration halo of several dm in the hosting amphibolites, characterized by biotitization and formation of holmquistite. An aplitic spodumene-free seam of about 10 cm symmetrically borders the pegmatites. No contact phenomena are observed along the micaschist-hosted dikes. Spodumene is the only lithium-bearing mineral. Its average content is 22 vol% (equivalent to 1.68 wt% Li₂O) in the amphibolite-hosted pegmatites and 15 vol% (equivalent to 1.13 wt% Li₂O) in the micaschist-hosted dikes. Such a significant difference is also shown by rubidium (1,100 ppm vs 880 ppm) and cesium (60 ppm vs 25 ppm). Beryllium and tin are the only other significant trace elements. They show average contents of about 100 ppm and 120 ppm, respectively, with maxima of 1,690 ppm beryllium and 1,500 ppm tin. No correlation is found between lithium, tin, and beryllium. Niobium and tantalum are very low. A Na/K ratio of 1.2 emphasizes the predominance of albite over microcline. There is no discernable correlation between spodumene and albite contents, or between lithium and any other alkalies. The average K/Rb ratio is 20, pointing to the high degree of fractionation. Spodumene contains 7.4% Li₂O and 0.45% FeO. There is no difference in the spodumene chemistry between the amphibolite-hosted and the micaschist-hosted pegmatites. Strong structural and textural evidence, mineral zoning, bulk composition corresponding to thermal minima in relevant experimental systems, and trace-element signature support an igneous derivation of the pegmatites. However, no granitic intrusion is exposed in the area, and the pegmatites could have been displaced from their source by tectonic events.     

阿尔金中段吐格曼地区花岗伟晶岩型稀有金属成矿特征与找矿预测

新疆若羌县阿尔金中段吐格曼地区是花岗伟晶岩型稀有金属成矿的有利地区,目前已发现吐格曼铍锂矿、吐格曼北锂铍矿和瓦石峡南锂铍矿,其中发育于吐格曼层状花岗岩中心的吐格曼铍锂矿和北部接触带的吐格曼北锂铍矿已达中型规模。本文总结了吐格曼地区稀有金属花岗伟晶岩的类型,报导了吐格曼铍锂矿和吐格曼北锂铍矿伟晶岩的特征与形成时代。并基于ASTER遥感岩体与伟晶岩光谱信息提取成果揭示花岗岩与花岗伟晶岩的分布,指出托巴片麻状二长花岗岩中段花岗伟晶岩区以及阿亚格黑云斜长花岗岩南接触带花岗伟晶岩群是稀有金属找矿靶区,指出吐格曼铍锂矿花岗伟晶岩形成于中奥陶世晚期(460Ma)南阿尔金洋闭合后阿中地块与柴达木地块碰撞过程的后碰撞阶段。     

华南幕阜山花岗伟晶岩的矿物化学特征及指示意义

华南晚中生代幕阜山花岗复式岩基内部及周缘广泛发育花岗伟晶岩脉,部分岩脉富含Li-Nb-Ta等元素,形成大型－超大型稀有金属矿床.本文以幕阜山北缘断峰山地区贫锂伟晶岩类和南缘仁里地区新发现的富锂伟晶岩为主要研究对象,通过详细的岩相学和主要及特征矿物（长石、云母、电气石、石榴子石、绿柱石、铌钽铁矿）的微区原位EPMA和LA-ICP-MS主微量元素地球化学的对比分析,深入探讨了伟晶岩的分类、成因演化及成矿潜力.按照特征矿物组合将伟晶岩划分为断峰山地区电气石伟晶岩、电气石－绿柱石伟晶岩、绿柱石伟晶岩、铌钽铁矿－绿柱石伟晶岩和仁里地区的锂电气石－锂云母伟晶岩5类.5类岩脉中的长石、云母、电气石和/或石榴子石的化学成分记录了不同程度花岗伟晶岩脉的演化阶段,按岩浆演化程度由低至高依次为电气石伟晶岩→电气石－绿柱石伟晶岩→绿柱石伟晶岩→铌钽铁矿－绿柱石伟晶岩→锂电气石－锂云母伟晶岩,并分别对应伟晶岩稀有金属富集程度分类中的无矿→（含Be）→富Be→富Be、Nb、Ta→富Li、Be、Nb、Ta阶段.这一结果表明仁里地区伟晶岩已演化至晚期富集多种稀有金属元素阶段,具有Li-Nb-Ta多金属成矿潜力,而断峰山地区的伟晶岩演化程度相对较低.断峰山电气石－绿柱石伟晶岩中的色带电气石晶体发育强烈成分环带,由内向外可明显分为5环,自核部至边部,Li、Zn、Ga、Ge、Nb、Ta、Sn、Pb等不相容元素和金属元素含量逐渐升高,清晰记录了正常岩浆演化序列及稀有金属富集过程.结合前人有关幕阜山花岗岩类的研究资料,本文认为幕阜山伟晶岩为该地区晚中生代巨量花岗质岩浆经历长期结晶分异作用晚期的分异产物.      

Classification and mineralization potential of the pegmatites of the Eastern Brazilian Pegmatite Province

The potential for Nb, Ta, Li, Sn-mineralization as well as for precious stones for the Eastern Brazilian Pegmatite Province (EBPP) has been evaluated on the basis of 530 K-feldspar and 550 muscovite major and trace element analyses. The EBPP is situated mainly in the State of Minas Gerais, but encompasses also parts of the States of Bahia, Espírito Santo and Rio de Janeiro. The EBPP is the largest pegmatite province of South America. It was divided into the pegmatite districts of Itambé, Araçuaí, Safira, Nova Era, Aimorés and Espera Feliz. This was done to test whether the pegmatites of these districts differ in their mineralization potential and how geotectonic setting influences mineralization potential. The fractionation diagrams such as Cs, Zn, Li, Be, Ba versus K/Rb, Cs versus Ta/(Ta + Nb), and U, Na₂O versus K/Cs for the pegmatite districts of Araçuaí and Safira show the widest range in fractionation. These pegmatite districts are leaders in the production of gem-quality tourmaline, aquamarine, morganite, and contain abundant spodumene, tantalite and columbite. In contrast, the Espera Feliz and Aimorés pegmatite districts are the most primitive districts examined and have a corresponding lack of rare-element mineralization. Literature data indicate that all studied pegmatites are of Brasiliano age, i.e., formed between 600 and 480?Ma. The pegmatites of Transamazonic age (1.9?Ga), found rarely in the study area, are of economic importance in the context of emerald mineralization, but seem to be of less importance for rare metal and other gemstone mineralization.     

川西甲基卡花岗伟晶岩型锂矿床中熔体、流体包裹体固相物质研究

川西甲基卡二云母花岗岩和伟晶岩内发育大量原生熔体包裹体和富晶体流体包裹体。为了查明甲基卡成矿熔体、流体性质与演化特征,运用激光拉曼光谱和扫描电镜鉴定了甲基卡花岗伟晶岩型锂矿床中二云母花岗岩及伟晶岩脉不同结构带内的原生熔体、流体包裹体的固相物质。分析结果表明,甲基卡二云母花岗岩石英内熔体包裹体的矿物组合为磷灰石+白云母、白云母+钠长石、白云母+石墨;伟晶岩绿柱石内富晶体流体包裹体的矿物组合主要为刚玉、富铝铁硅酸盐+刚玉+锂辉石、锂辉石+石英+锂绿泥石;伟晶岩锂辉石内富晶体流体包裹体的矿物组合主要为磷灰石、锡石、磁铁矿、石英+钠长石+锂绿泥石、萤石、富钙镁硅酸盐+富铁铝硅酸盐+富铁硅酸盐+石英;花岗岩浆熔体与伟晶岩浆熔体(流体)具有一定的差异,成矿熔体、流体成分总体呈现出碱质元素(Na、Si、Al)、挥发分(F、P、CO_2)含量增高及基性元素(Fe、Mg、Ca)降低的特征;包裹体中子矿物与主矿物的化学成分具有一定的差别,揭示出伟晶岩熔体(流体)存在局部岩浆分异作用,具不混溶性及非均匀性。因此认为,伟晶岩熔浆(流体)为岩浆分异与岩浆不混溶共同作用的产物,挥发分含量的增高(F、P、CO_2)使伟晶岩能够与稀有金属组成各类络合物或化合物,这对于稀有金属成矿起到了至关重要的作用。     

辽东岫岩地区古元古代花岗伟晶岩锆石U-Pb年龄、地球化学特征及地质意义

辽东岫岩地区位于胶—辽—吉古元古代造山/活动带内,区域内广泛存在花岗质伟晶岩脉或岩体,对其进行研究具有重要的构造意义。研究区出露大量古元古代花岗伟晶岩,前人将其统一划归到花岗质混杂岩和辽河岩群内。本文通过详细的野外地质调查和室内综合研究,将该套花岗伟晶岩脉解体为出来,重新厘定为新的填图单元。本文对研究区2件花岗伟晶岩样品进行岩石学、岩石地球化学、锆石LA-ICP-MS稀土微量元素和U-Pb定年的综合研究,获得花岗伟晶岩的原岩年龄,并对其岩石地球化学、成因和构造环境进行了探讨。花岗伟晶岩主要矿物组合为钾长石+斜长石+石英±白云母±电气石,花岗伟晶结构,块状构造。岩石地球化学分析结果显示其均匀具有一致的地球化学特征。它们均显示高的SiO2(72.1%~75.3%)、Al2O3(13.5%~16.4%),低CaO(1.42%~2.03%)、MgO(0.15%~0.76%)、P2O5(0.01%~0.02%%)、TiO2(0.06%~0.17%)等含量;稀土元素总量偏低,稀土富集、重稀土亏损,稀土配分曲线右倾型,明显的正δEu异常;微量元素富集大离子亲石元素(Cs、Rb、Ba、U),相对亏损高场强元素(Nb、Ta、Ti)等特征。样品(DST-TW1和WJG-TW1)锆石CL图像强度均较弱,前者大部分锆石不能反映矿物内部结构,后者大部分锆石能显示弱振荡环带,这一特征与锆石U含量均较高(1253.1×10-6~12861.5×10-6、874.5×10-6~5319.1×10-6)相吻合。锆石虽具有岩浆锆石的自形特征,但其Th/U值(0.01~0.26和0.01~0.62)较低,稀土配分模式显示热液锆石特征,在(Sm/La)N—La和Ce/Ce*—(Sm/La)N图解上偏热液锆石区域,此花岗伟晶岩脉可能是母岩浆高度结晶分异后的残余岩浆热液结晶而成,偏热液性质。本文研究的2件样品(DST-TW1和WJG-TW1)年龄分别为1864±20 Ma(MSWD=0.19)和1903.6±4.7 Ma(MSWD=0.041),其侵位时间介于1.9~1.86 Ga之间。从岩石地球化学、形成时代推测其物源与研究区周围~1.87 Ga的S型花岗岩具有亲缘关系。从构造环境来看,研究区内古元古代花岗伟晶岩形成于胶—辽—吉造山带弧陆碰撞结束后伸展的构造体制下,在主期花岗质岩浆上涌之后,地壳在不断伸展和松弛垮塌,大量残余岩浆或岩浆热液上涌形成伟晶岩的岩脉、岩墙或岩体,侵位时代从~1.9 Ga到~1.74 Ga。从而推测胶—辽—吉造山带在碰撞后的构造折返过程中一直处于伸展的构造机制,后造山阶段至少持续了160 Ma。