山西大同新生代火山岩熔融相平衡的实验研究

通过低压熔融相平衡实验，研究山西大同火山群玄武岩在结晶分离作用过程中液相成分的演化规律，探讨了矿物和溶浆之间元素的分配。在１００ｋＰａ，ｆｏ２＝ＮＮＯ，Ｔ＝１１００°～１３００℃条件下，矿物结晶顺序为Ｏ１→Ｐ１→Ｃｐｘ。橄榄石为液相线矿物。橄榄石－熔体Ｆｅ２－－Ｍｇ２－交换反应的分配系数是一个与温度无关的常数、残余液相线成分取决于晶出矿物相的化学成分及含量。Ｏ１＋ＣｐＸ＋Ｐ１饱和液相成分的Ｏ１－Ｄｉ－Ｓｉｌ和Ｏ１－Ｄｉ－Ｎｅ三元系相图清楚地反映了熔岩低压结晶作用的趋势，低压下熔浆的主要元素变化很大程度上依赖于母岩浆ＳｉＯ２饱和程度。     

广西大容山——十万大山岩带紫苏辉石堇青石花岗岩套矿物学研究

大容山－－十万大山岩带中的紫苏辉石堇青石花岗岩套位于桂东南海西－－印支褶皱带，富含堇青石、紫苏辉石、石榴石、矽线石、红柱石、刚玉等。矿物组合复杂，成因多样，可划分为岩浆结晶成因、变质残留成因和反应成因３种类型。根据各类岩石中矿物的特征分析，认为岩套中的花岗岩类岩石部分来源于深熔花岗岩奖的源岩不熔残余，另一部分来自围岩捕虏体变质后又被熔浆改造的不熔残余，是由区域变质岩经不同温压条件，不同深度熔作用形     

富锂氟含稀有矿化花岗质残余熔体的地质和地球化学依据

通过对地质学、地球化学、实验岩石学和包裹体等方面的研究,综合论证了富氟锂含稀有金属矿化花岗岩,主要是由经过充分分异演化的超酸性、过铝、富挥发分、富含稀有金属元素的花岗质残余熔浆直接结晶而成的,并具有岩浆一热液过渡阶段的一般特征。     

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     

岩浆熔体中的挥发性组分及其岩石学意义

文章论述了挥发性组分在岩浆熔体中的溶解行为及其在岩浆熔体中溶解的限制条件，在此基础上讨论了挥发性组分对岩浆演化及岩石学成因方面的意义：溶解在岩浆中的水可明显地改变矿物从岩浆中结晶出的顺序，改变岩浆熔体的演化轨迹。含水玄武岩浆在其早期结晶出铁的氧化物并与Ｓｉ和富碱质组分分异从而使其成为Ｆｅ亏损的钙－碱性系列的岩浆，而无水玄武岩浆演化的早期不能结晶出磁铁矿，因而演化成富Ｆｅ且具中等Ｓｉ含量的拉斑玄武岩系列。溶解于岩浆中Ｈ２Ｏ的离解将产生高ｆＯ２环境，从而导致Ｆｅ的氧化物在岩浆演化早期沉淀。     

伟晶岩型稀有金属矿床成矿作用研究进展

伟晶岩型矿床是世界上重要的稀有金属矿床类型之一,也是当前国际矿床学研究热点之一。近年来该类稀有金属矿床在分类、成矿流体及成矿物质来源、伟晶岩成岩方式和稀有金属富集机制等方面的研究取得了一些重要进展。伟晶岩通常与母质岩浆具有密切的时空关系,但不少也与母质岩浆无成因关系。伟晶岩稀有金属矿床成矿熔体/流体具有低黏度、富水、高分散性、富碱等性质,可导致P、F和B等元素在伟晶岩中的极端富集,使其与稀有金属组成各类络合物或化合物而迁移与富集。富含Li-Cs-Ta(LCT)型伟晶岩与S型花岗岩关系紧密,成矿物质主要起源于黑色页岩等海相沉积物质,而富含Nb-Y-F(NYF)型伟晶岩常与A型花岗岩联系紧密,属同源岩浆演化和矿化。花岗质岩浆分异结晶和地壳或地幔岩石的部分熔融是伟晶岩两种主要的形成方式。流体不混溶作用、富助熔组分花岗岩浆高度结晶分异和热液交代作用3种富集机制可用于解释伟晶岩型稀有金属矿床的形成。     

苏州氟铁云母岩--富氟A型花岗岩浆的残余分异物

位于苏州A型花岗岩主体相晚阶段衍生物（碱长花岗岩）上部，基本上由新矿物－氟铁云母组成的单矿物岩，具有独特的产状、结构、构造、岩石化学、矿物学、地球化学和成矿作用特征。种种典型的宏观、微观地质特征和合成氟铁云母的实验资料揭示，氟铁云母岩主要是从A型花岗岩浆演化至晚阶段熔离出来的富F，Fe和亲石性矿化元素及富碱性元素（且K＞＞Na)而相对贫水的高温硅酸盐熔体中直接结晶固化所成。氟铁云母岩应属一种新的岩浆岩，依产地命名为姑苏岩。姑苏岩拟归入岩浆云英岩范畴为宜。提出了包括姑苏岩、含黄玉的石英－氟铁云母云英岩（苏州岩）和氟铁云母碱长花岗岩等在内的苏州A型花岗岩的成岩、成矿模式。     

花岗质微粒交生体的成因及地质意义

在某些塑性变形的花岗质石（主要是同构造花岗岩）中，发现一种不同于糜棱基质的微细粒矿物集合体－－微粒交生体。它充填于大粒级矿物的三结点和接合缝内，含量一般为２－６ｖｏｌ％由微粒石英、钾长石、蠕状石等组成，成分上与花岗质岩浆晚期结晶产物相当。根据其产状、成分、岩相学特征及有关实验资料，认为它是较镪应力作用下岩石所含量熔体残余呈初体等）的结晶产物，可做为岩体同构造侵位或塑性变形岩石部分熔融作用的显微构造     

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。     

川西甲基卡308号脉的矿物学特征及其岩浆- 热液演化示踪

甲基卡稀有金属矿床是亚洲规模最大的伟晶岩型锂矿床，308号脉为其中出露面积最大的伟晶岩脉。308号脉具有完善的分带性:细粒白云母- 钠长石- 石英带（Ⅰ）、中粗粒钠长石- 石英- 微斜长石带（Ⅱ）、中粒电气石- 钠长石- 石英带（Ⅲ）、中粗粒锂辉石- 钠长石- 石英带（Ⅳ）和中细粒锂辉石- 钠长石- 石英带（Ⅴ），并且富含稀有金属矿物（如锂辉石、绿柱石、锡石和铌钽氧化物），因此是系统研究伟晶岩演化历史和成岩成矿机制的理想实验对象。308号脉的矿物学研究较为薄弱，其岩浆- 热液演化过程及该过程中熔- 流体性质的变化规律，以及稀有金属的富集过程和影响因素尚不清楚。本文选取该脉各结构带中的贯通性矿物云母、磷灰石，以及稀有金属矿物锂辉石和特征性矿物电气石，通过详细的电子探针工作，分析它们的产状、结构特征、化学组成及其变化，结果表明:① 308号脉边部Ⅰ带（高温结晶）中电气石的出现（~5%）反映伟晶岩初始熔体具有富B的特征（>2%）；锂辉石在Ⅳ和Ⅴ带内的大量结晶说明初始熔体可能具有富Li的性质；主要含氟矿物电气石、磷灰石和云母类在岩石中的含量均较低，并且原生磷灰石具有相对偏低的F浓度（<3%），仅能形成于富F环境中的锂云母矿物也十分稀少，这些特征均表明308号脉初始熔体很可能具有较低的F含量；② 伟晶岩体系演化至Ⅴ带时发生流体出溶现象，自此进入岩浆- 热液过渡阶段，出溶流体可能具有富Cs和贫F的性质；③ 原生白云母和电气石化学成分的规律性变化说明308号脉的演化过程很可能不存在外来流体的加入；④ 308号伟晶岩的成岩和锂成矿过程主要受分异结晶作用支配，有限的出溶流体规模和伟晶岩分异演化程度（仅演化至岩浆- 热液过渡阶段，未充分进入热液阶段）对锂辉石的结晶和保存都起到了重要作用。     

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.     

Geochemical and Sm–Nd isotopic study of titanite from granitoid rocks of the eastern Dharwar craton,southern India

Titanite occurs as an accessory phase in a variety of igneous rocks, and is known to concentrate geologically important elements such as U, Th, rare earth element (REE), Y and Nb. The differences in the abundances of the REEs contained in titanite from granitoid rocks could reflect its response to changes in petrogenetic variables such as temperature of crystallization, pressure, composition, etc. Widespread migmatization in the granodiorite gneisses occurring to the east of Kolar and Ramagiri schist belts of the eastern Dharwar craton resulted in the enrichment of the REEs in titanite relative to their respective host rocks. A compositional influence on the partitioning of REEs between titanite and the host rock/magma is also noticed. The relative enrichment of REEs in titanite from quartz monzodiorite is lower than that found in the granodioritic gneiss. Depletion of REE and HFSE (high field-strength elements) abundances in granitic magmas that have equilibrated with titanite during fractional crystallization or partial melting has been modelled. As little as 1% of titanite present in residual phases during partial melting or in residual melts during fractional crystallization can significantly lower the abundances of trace elements such as Nb, Y, Zr and REE which implies the significance of this accessory mineral as a controlling factor in trace element distribution in granitoid rocks. Sm–Nd isotope studies on titanite, hornblende and whole rock yield isochron ages comparable to the precise U–Pb titanite ages, invoking the usefulness of Sm–Nd isochron ages involving minerals like titanite.     

喜马拉雅造山带中新世岩浆型石榴子石的矿物化学特征:从高Sr/Y花岗岩到淡色花岗岩

石榴子石是演化花岗岩常见的重要副矿物之一,但石榴子石地球化学特征如何随岩浆演化而变化是有待探讨的问题之一。雅拉香波片麻岩穹隆发育年龄分别为20. 3±0. 5Ma和20. 1±0. 3Ma(锆石U-Pb年龄)的高Sr/Y比二云母花岗岩(TMG)和淡色花岗岩(Grt-LG)。虽然两类花岗岩都含石榴子石,且在形成时代和Sr-Nd同位素组成上相似,但在元素地球化学特征上具有明显的差异,淡色花岗岩和二云母花岗岩分别代表演化程度较高和较原始的岩浆。在同一件样品中,在石榴子石颗粒之间,存在一定程度的微量元素地球化学特征的不均一性,反映了局部熔体地球化学特征。在两类花岗岩中,岩浆型石榴子石具有以下相似的地球化学特征:(1)从核部到边部,Mn和HREE含量降低,表现出典型的生长环带特征;(2)富集HREE,亏损LREE;和(3)显著的Eu负异常。但在关键微量元素Zn、Sc和Y上,具有明显的差异性。在花岗质岩浆演化过程中,贫Fe、Mg和Mn矿物相的分离结晶作用,导致残留熔体的Ca和Sr含量降低,Eu负异常幅度增大,Sc、Zn、Y和HREE增高,是导致淡色花岗岩石榴子石相应元素含量增高的主要原因。上述观测表明:高Sr/Y花岗岩也可以结晶石榴子石,与通常的淡色花岗岩石榴子石相比,这些石榴子石的Sc、Zn和Y含量和Eu异常幅度明显较低。但随分异程度的升高,石榴子石的元素地球化学特征与源自变沉积岩的淡色花岗岩的类似。因此,花岗岩中的石榴子石矿物化学特征变化记录了花岗岩岩浆演化的重要信息。     

Textural and chemical evolution of a fractionated granitic system: the Podlesí stock, Czech Republic

The Podlesí granite stock (Czech Republic) is a fractionated, peraluminous, F-, Li- and P-rich, and Sn, W, Nb, Ta-bearing rare-metal granite system. Its magmatic evolution involved processes typical of intrusions related to porphyry type deposits (explosive breccia, comb layers), rare-metal granites (stockscheider), and rare metal pegmatites (extreme F–P–Li enrichment, Nb–Ta–Sn minerals, layering). Geological, textural and mineralogical data suggest that the Podlesí granites evolved from fractionated granitic melt progressively enriched in H₂O, F, P, Li, etc. Quartz, K-feldspar, Fe–Li mica and topaz bear evidence of multistage crystallization that alternated with episodes of resorption. Changes in chemical composition between individual crystal zones and/or populations provide evidence of chemical evolution of the melt. Variations in rock textures mirror changes in the pressure and temperature conditions of crystallization. Equilibrium crystallization was interrupted several times by opening of the system and the consequent adiabatic decrease of pressure and temperature resulted in episodes of nonequilibrium crystallization. The Podlesí granites demonstrate that adiabatic fluctuation of pressure (“swinging eutectic”) and boundary-layer crystallization of undercooled melt can explain magmatic layering and unidirectional solidification textures (USTs) in highly fractionated granites.     

Volcanoplutonic association of felsic rocks in the rare-metal ore units of Transbaikalia: Geochemistry of rocks and melts, age, and P-T conditions of their crystallization

The results of study of chemical composition, mineral-forming medium, P-T conditions of crystallization, and the age characteristics of subvolcanic felsic rocks that are spatially associated with rare-metal granite massifs in the ore units of Transbaikalia (Sherlovaya Gora, Khangilay, Bukuka, Belukha, and Shumilovka) give grounds for defining cogenetic volcanoplutonic associations. These associations within the studied region consist of rare-metal granites, ongonites, rhyolites, ongorhyolites, and trachyrhyodacites, which have much in common, but also many differences. The common chemical features of these rocks are their peraluminium signature, low mafic index and basicity, as well as enrichment (as compared to crust) in trace lithophile elements (Li, Rb, Nb, Ta, Sn, W, and F), the low contents of Zr, REE, and Sr, and the similar distribution of trace and refractory elements. At the same time, these rocks differ in the proportions of sodium and potassium, levels of concentrations of lithophile trace and refractory elements, REE distribution patterns, P-T regimes of crystallization, and the volatile composition. The composition of melts from all types of the studied rocks and trace element distribution between melts and rocks were studied on the basis of ion-microprobe analysis of rehomogenized glasses of melt inclusions in quartz. The highest concentrations of lithophile trace elements in the melt, including Cs (up to 300 ppm), Rb (up to 1002 ppm), U (up to 42 ppm), and Th, were found in the trachyrhyodacites of the Bukuka-Belukha ore unit; in terms of Li content this melt is comparable with the Ary-Bulak ongonites (690 and 715 ppm Li, respectively), and differ by an order of magnitude in the contents of refractory and rare-earth elements (total REE 94.4 and 5.44 ppm, respectively), which is indicative of a lower differentiation degree of this melt as compared to ongonites. Potassic rhyolites are peculiar in the low content of lithophile trace elements, but residual melt reveals notable enrichment in Li (up to 130 ppm) and Nb (up to 120 ppm). The accumulation of U in the residual melt of the trachyrhyodacitic and rhyolitic magmas of Eastern Transbaikalia may indicate their high potential for postmagmatic uranium ore formation. Isotope-geochronological studies (Rb-Sr isotope system) of the Sherlovaya Gora ore unit showed that the entire complex of volcanoplutonic association (granites, ongonites, rhyolites, and ongorhyolites) formed almost simultaneously within an interval of 4 Ma: from 145.7 ± 1.3 Ma at IR_Sr = 0.70507 ± 20 and MSWD = 0.48 to 141.5 ± 1.0 Ma at IR_Sr = 0.70359 ± 63 Ma and MSWD = 0.24. A spatial association of the subvolcanic rock complex with rare-metal granite massifs, their formation within a common age interval, geochemical features, and P-T conditions of crystallization suggest that they are genetically related but were derived from variably evolved sources, which originated from a single protolith under the action of mantle plume that existed beneath Central Asia at that time (Yarmolyuk and Kovalenko, 2003).     

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.     

喜马拉雅淡色花岗岩——关键金属Sn-Cs-Tl的富集机制

关键金属是全球高科技产业不可或缺的战略性资源,其富集机制和成矿作用是目前国际矿床学研究的热点之一。我们对喜马拉雅带吉隆和亚东地区淡色花岗岩开展系统的地球化学研究,发现侵入到藏南拆离系的淡色花岗岩含有较高的Sn、Cs、Tl、Be、W、B、Li和Bi。全岩元素地球化学分析表明,这些淡色花岗岩具有如下特征：（1）富集关键金属元素;（2）为原始岩浆经历斜长石、锆石、独居石、磷灰石、云母分离结晶作用后的残余熔体;（3）关键元素的富集和矿化与花岗岩高度分离结晶作用密切相关。随着分异程度的增强,岩浆变为富挥发分的高SiO₂体系,关键金属元素在残余熔体中富集,并且最后可能形成具有工业价值的矿床。由于地球化学特征的相似性,Cs和Tl呈类质同象替代钾、铷进入云母中。富集关键金属元素的花岗岩在时间上和空间上属于与藏南拆离系相关的同构造侵位花岗岩,藏南拆离系的活动促使了原始岩浆的广泛分离结晶作用,以及后期的关键金属元素（如Rb、Cs和Tl）的富集。     

藏南拿日雍措片麻岩穹窿淡色花岗岩稀有金属的富集

拿日雍措穹窿(错那洞穹窿)位于北喜马拉雅穹窿的东部,穹隆内花岗岩种类较多,有淡色花岗岩、含石榴子石淡色花岗岩、片理化淡色花岗岩、含石榴子石和含绿柱石伟晶岩.这些花岗岩为经历了斜长石、锆石、独居石、磷灰石、富Ti矿物等分离结晶作用而形成的高度演化花岗岩,相对于维氏世界花岗岩平均值,富集Bi、Cs、Li、Sn、Be、Pb、B、W、Ta等稀有金属成矿元素,略贫Nb元素.同时,围岩也相对富集稀有金属元素.全岩地球化学分析表明,引起拿日雍措穹隆淡色花岗岩富集稀有金属成矿元素的因素是分离结晶作用和热液交代作用.高度演化淡色花岗岩在喜马拉雅造山带广泛分布,铌铁矿、钽铁矿、锡石和绿柱石等稀有金属矿物已在多处露头被识别,暗示了喜马拉雅淡色花岗岩是未来稀有金属矿产勘探的重要靶区.     

湖南香花岭地区花岗岩中锂对成岩成矿的制约

锂（Li）是一种战略关键金属,岩浆阶段主要在花岗质岩石中得到富集和结晶。由于具有不相容和富挥发性等性质,锂对花岗岩的成岩成矿具有重要的制约。文章利用电子探针、LA-ICP-MS 等分析手段,对湖南香花岭地区癞子岭和尖峰岭花岗岩进行系统岩相学、主微量和矿物学研究,结果表明：（1）花岗质岩浆结晶分异过程中,Li 含量逐渐升高,大幅度降低了熔体粘度,增大了结晶温度区间,花岗质岩浆得到充分结晶分异,导致花岗岩的垂直分带;（2）花岗岩中Li 与稀有金属含量呈正相关关系,Li 与Ta、Nb、Sn 等稀有金属具有协同成矿作用;（3）花岗岩中云母类矿物具有向富Li 演化的趋势,以铁锂云母为主,随着铁锂云母的结晶,Nb、Ta、Sn 等稀有金属相继析出,导致晚期云母中Ta、Nb 等含量降低。熔体中H2O、F 等对花岗质岩浆的性质和结晶分异有较大影响,但不足以致使花岗岩呈垂直分带。     

Evidence for lithium-aluminosilicate supersaturation of pegmatite-forming melts

New experimental data on the solubility of lithium (Li) at spodumene (LiAlSi₂O₆) and petalite (LiAlSi₄O₁₀) saturation at 500 MPa and 550–750 °C reveal evidence for lithium supersaturation of pegmatite-forming melts before the formation of Li-aluminosilicates. The degree of Li enrichment in granitic melts can reach ~11,000 ppm above the saturation value before the crystallization of Li-aluminosilicate minerals at lower temperatures. Comparison of the experimental results with the spodumene-rich Moblan pegmatite (Quebec) is consistent with extreme Li enrichment of the pegmatite-forming melt prior to emplacement, which cannot be explained with equilibrium crystallization of Li-aluminosilicates from a common granitic melt. The results of this study support the model of disequilibrium fractional crystallization through liquidus undercooling as the most plausible mechanism for the generation of such Li-rich ore resources.