江西宜春黄玉-锂云母花岗岩中的铍矿化作用:铍磷酸盐矿物组合

江西宜春黄玉-锂云母花岗岩是著名的稀有金属花岗岩,P_2O_5含量较高(平均0.56%)。该花岗岩全岩 Be 含量一般超过100×10~(-6),最高可达720×10~(-6),属于铍矿化花岗岩。本文利用电子探针技术对宜春铍矿化花岗岩中的铍磷酸盐及其共生矿物进行了系统研究。研究发现羟磷铍钙石是该花岗岩中的最重要铍矿物(BeO=15%～16%),偶尔亦可见磷钠铍石,它们主要呈晶间副矿物出现在岩体的中部。与铍矿物共生的矿物仍主要为磷酸盐矿物,如氟磷灰石、磷铝锂石、磷铝钠石,表明铍矿化作用与熔体中磷的聚集作用有显著关系。研究认为,宜春黄玉-锂云母花岗岩中铍以磷酸盐矿物形式结晶,而不是硅酸盐矿物,其主要原因可能为该花岗岩的结晶晚期磷的活度远远高于硅的活度,因此,P 优先作为成网离子与铍结合形成铍磷酸盐矿物。     

江西宜春黄玉-锂云母花岗岩石中的铍矿化作用：铍磷酸盐矿物组合

江西宜春黄玉-锂云母花岗岩是著名的稀有金属花岗岩,P2O5含量较高（平均0.56%）.该花岗岩全岩Be含量一般超过100×10^-6,最高可达720×10^-6,属于铍矿化花岗岩.本文利用电子探针技术对宜春铍矿化花岗岩中的铍磷酸盐及其共生矿物进行了系统研究.研究发现羟磷铍钙石是该花岗岩中的最重要铍矿物（BeO=15%～16%）,偶尔亦可见磷钠铍石,它们主要呈晶间副矿物出现在岩体的中部.与铍矿物共生的矿物仍主要为磷酸盐矿物,如氟磷灰石、磷铝锂石、磷铝钠石,表明铍矿化作用与熔体中磷的聚集作用有显著关系.研究认为,宜春黄玉-锂云母花岗岩中铍以磷酸盐矿物形式结晶,而不是硅酸盐矿物,其主要原因可能为该花岗岩的结晶晚期磷的活度远远高于硅的活度,因此,P优先作为成网离子与铍结合形成铍磷酸盐矿物.     

江西雅山黄玉锂云母花岗岩中富磷锆石研究

雅山黄玉锂云母花岗岩是雅山复式岩体的最晚阶段岩体,具较高的磷含量（ＷＰ２Ｏ５＝０．１５％￣０．５５％）,长石矿物是磷的主要赋存矿物,磷以ＰＡｌＳｉ－２替换方式进入长石结构中;锆石是雅山花岗岩重要的稀有元素副放物之一,它除了高度富铪、铀外,与一般锆石相比,还表现出显著富磷的特征,Ｐ２Ｏ５含量变化主要为ＷＰ２Ｏ５＝０．２３％￣４．９６％。磷主要以（Ｙ,ＨＲＥ３Ｅ,Ｆｅ）＾３＋Ｐ＾５＋（Ｚｒ,Ｈｆ）＾４     

硅酸盐-磷酸盐平衡反应对熔体中磷制约实验

目前，根据磷灰石溶解度模型、P在碱性长石与熔体相间的分配以及黑云母、锰铝榴石、透锂长石与对应的磷酸盐（包括斜磷锰铁矿、磷铝锂石-羟磷锂铝石）的平衡研究，已对过铝质岩浆中P的归宿进行了有效的平衡。但未见锰铝榴石-磷灰石的平衡研究。由于锰铝榴石-磷灰石矿物共生组合是花岗岩和LET型伟晶岩中最常见的矿物组合，直到岩浆演化晚期才出现锂辉石-磷铝锂石-羟磷锂铝石的组合。为此，本文实验研究锰铝榴石-磷灰石平衡反应，对过铝质岩浆体系中P溶解度起控制作用。     

华南富氟花岗岩高磷和低磷亚类型对比

根据全岩Ｐ２Ｏ５含量的多寡可将华南富氧花岗岩分为高磷亚类和低磷亚类,它们之间具较大的地球化学差异。高磷亚类以低硅、强过铝和低的ＲＥＥ总量为特征,而低磷亚类则相反。在长石、云母等矿物化学成分上这两亚类花岗岩也有所差异。高磷亚类花岗岩中磷以长石中结构磷和磷铝锂石形式存在,而低磷亚类花夺中的磷则主要存在于磷灰石等磷酸盐矿物中。     

江西雅山花岗岩长石中磷的分布及意义

雅山富氟高磷花岗岩具较高的全岩磷含量（０．１５％～０．５５％）,长石是磷的主要赋存矿物,磷以ＰＡｌＳｉ－２替换方式进入长石结构中。各种结晶习性的长石的磷含量各不相同。早世代钠长石和雪球结构中钠长石包裹体的结晶较早,平均磷含量分别为０．１８％和０．１９％,而晚世代钠长石和环带钾长石中钠长石嵌晶的结晶稍晚,具较高的平均磷含量（分别为０．２５％和０．２３％）。钾长石的磷含量相对于钠长石总体上较低,早期结晶的雪球结构主晶钾长石和环带钾长石的磷含量最低,分别为０．０４％和０．０２％,晚期细粒钾长石的平均磷含量略高（０．１９％）。长石对全岩磷的贡献率还与磷锂铝石等磷酸盐副矿物是否达到饱和有关,当无磷锂铝石结晶时,长石磷的贡献率约为７６％,反之则约为３１％。     

九岭式狮子岭岩体型稀有金属成矿作用研究进展及其找矿意义

赣西北是我国重要的稀有金属成矿区,成矿作用主要集中于武功山隆起和九岭隆起,其中的武功山隆起产有我国最大的岩体型稀有金属矿床414矿,在九岭隆起是否也能找到类似于414的大型稀有金属矿床成为业界关注的焦点。本文在华南稀有稀散和稀土矿产调查评价项目开展过程中,查明了赣西北九岭地区的狮子岭岩体也存在类似的稀有金属矿化,矿化主要赋存于黑磷云母—含锂白云母碱长花岗岩、锂(白)云母碱长花岗岩和黄玉锂云母碱长花岗岩三类岩石中,三类岩石的分带特点与武功山隆起雅山含矿岩体从Ⅴ带的二云母碱长花岗岩到Ⅱ带的黄玉—锂云母—钠长石花岗岩演变趋势有非常明显的相似性。同时,详细的矿物学研究表明,狮子岭岩体稀有金属矿化特征与414矿也存在一定差异,如狮子岭黄玉—锂云母碱长花岗岩中磷锂铝石超常富集,含量可到4%～5%,已成为矿石中锂的主要载体之一;岩体中绿柱石、富钽锡石、铌钽铁矿、钽铌铁矿等工业稀有金属矿物也普遍存在,这些发现为该地区Li、Be、Ta及Sn的找矿工作部署提供了直接依据。同时,文章对九岭地区锂矿资源的成矿潜力、成矿机制以及华南地区岩体型锂矿找矿方向进行了探讨,深化了稀有元素在花岗岩类中成矿作用的认识,对华南地区稀有金属的找矿工作可能也将产生积极的影响。     

江西雅山黄玉锂云母花岗岩中铯矿物的电子探针研究

江西宜春雅山花岗岩是典型的高度分异型稀有金属花岗岩。通过对其最晚期花岗岩———黄玉锂云母花岗岩的钻孔样品和近地表样品的研究,发现岩体中主要有两种铯矿物:铯沸石和富铯锂云母。铯沸石是第一次在花岗岩中发现,其产状主要有两类:一类包裹于石英中,颗粒小,只有2～10μm,单个颗粒成分均匀,Si/Al比值和Poll值(%)犤=100×Cs/(Na+K+Rb+Cs)犦分别为2.13～2.65和57～89;另一类赋存于钠长石晶隙间,颗粒大,多为几百μm,单个颗粒成分不均匀,Si/Al比值和Poll值分别为2.20～2.45和75.6～88.2。富铯的云母类矿物分布较普遍,主要呈四种产状,分别为钾长石雪球中的带状富铯锂云母、云母边部的环边富铯云母、叶脉纹理状富铯云母和主矿物中的富铯云母包裹体,并根据成分中Si/Al比值和Cs的摩尔分数(%)犤=100×Cs/(Cs+K)犦,将富铯的云母类矿物分为含铯锂云母、富铯锂云母和铯锂云母三类,其中Cs替代K,Cs完全替代K形成的铯锂云母可能是锂云母系列中的铯端员新矿物。钻孔样品中的富铯云母类矿物以带状结构和环边结构最为发育,且成分主要属于含铯锂云母和富铯锂云母这两个部分,而近地表样品中则以环边结构和叶脉纹理状结构为特征,成分多为铯锂云母。铯沸石和富铯云母的产状及地球化学特征均表明,雅山岩体原始岩浆中碱金属经     

新疆白石头泉高铷氟花岗岩不同相带云母成分及其演化

白石头泉含黄玉花岗岩体在露头上显示很好的岩性分带,从下至上依次为:淡色花岗岩(a带)、含天河石花岗岩(b带)、天河石花岗岩(c带)、含黄玉天河石花岗岩(d带)和黄玉钠长花岗岩(e带).岩体组成矿物主要为石英、钾长石(部分富铷的为天河石)、钠长石、黄玉和云母,副矿物为锰铝榴石和萤石.总体说来,从a带到c带,云母的Al、Mn、F和Rb含量递增,Fe、Mg和Ti含量递减;Li含量从a带到b带和c带递增,但b带和c带之间变化不明显.从c带到e带,随着Fe、Mg和Ti的减少,总体上表现为Al、Li递增,F、Mn和Rb递减的演化方向,但Li、F、Mn和Rb在c带和d带之间变化不明显,d带和e带之间却表现出急剧的变化.e带中的次生云母与原生云母相比,前者F、Li高而Al低,从a带到e带,Na K变化不明显.云母成分的这些变化特征与岩体的演化趋势相一致.白石头泉岩体与世界上其他地方类似花岗岩相比,没有出现锂云母这种高度富锂矿物,这可能与岩体中锂含量较低有关.     

江西西北部锂及稀有金属成矿条件及找矿潜力分析

江西西北部地区锂及稀有金属矿成矿地质条件优越,有闻名全国的雅山、同安等超大型稀有金属矿床及众多含锂瓷石矿床,矿床类型较多,资源潜力巨大。本文通过论述江西西北部地区锂及稀有金属矿床的成矿地质背景、主要锂矿床地质特征、锂矿床成因及成矿模式,总结该区锂及稀有金属矿床成矿规律、找矿标志和找矿潜力。结果表明:江西西北部地区锂及稀有金属矿属岩浆晚期残留岩浆气液生成,其找矿标志为多期次侵入浅色细粒花岗岩且花岗岩中F、Nb、Ta、Li、Rb、Cs含量高,隆起区断裂构造发育和相互交切部位,钠长石化、锂云母化、黄玉化等蚀变现象,Li、Nb、Sn、W等亲氧元素异常,Nb、Ta、Sn、W等重矿物异常等。通过对甘坊及雅山地区锂资源量进行半定量估算,根据雅山地区物化探异常走势图及成矿岩体标志等,认为路口—雅山、高岭—江家岭为两个重要找矿潜力区。     

Residence of REE, Y, Th and U in Granites and Crustal Protoliths; Implications for the Chemistry of Crustal Melts

A systematic study with laser ablation—ICP-MS, scanningelectron microscopy and electron microprobe revealed that 70–95wt% of REE (except Eu), Y, Th and U in granite rocks and crustalprotoliths reside within REEYThU-rich accessories whose nature,composition and associations change with the rock aluminosity.The accessory assemblage of peraluminous granites, migmatitesand high-grade rocks is composed of monazite, xenotime (in low-Cavarieties), apatite, zircon, Thorthosilicate, uraninite andbetafite-pyrochlore. Metaluminous granites have allanite, sphene,apatite, zircon, monazite and Thorthosilicaie. Peralkaline graniteshave aeschinite, fergusonite, samarskite, bastnaesite, fluocerite,allanite, sphene, zircon, monazite, xenotime and Th-orthosilicate.Granulite-grade garnets are enriched in Nd and Sm by no lessthan one order of magnitude with respect to amphibolite-gradegarnets. Granulitegrade feldspars are also enriched in LREEwith respect to amphibolite-grade feldspars. Accessories causenon-Henrian behaviour of REE, Y, Th and U during melt—solidpartitioning. Because elevated fractions of monazite, xenotimeand zircon in common migmatites are included within major minerals,their behaviour during anatexis is controlled by that of theirhost. Settling curves calculated for a convecting magma showthat accessories are too small to settle appreciably, beingseparated from the melt as inclusions within larger minerals.Biotite has the greatest tendency to include accessories, therebyindirectly controlling the geochemistry of REE, Y, Th and U.We conclude that REE, Y, Th and U are unsuitable for petrogeneticalmodelling of granitoids through equilibrium-based trace-elementfractionation equations. KEY WORDS: accessory minerals; geochemical modelling; granitoids; REE, Y, Th, U     

Multistage Growth of a Rare-Element, Volatile-Rich Microgranite at Argemela (Portugal)

The small Argemela microgranite body in central Portugal displaysmany of the mineralogical and chemical features characteristicof peraluminous, Li, P-rich, rare-element pegmatites. Its mineralogyconsists predominantly of quartz, albite, white mica (partlyreplaced by lepidolite) and a phosphate of the amblygonite series.K-feldspar is noticeably absent or scarce. Cassiterite, beryland columbite are the main accessories. The microgranite showsextreme enrichment in incompatible elements such as F, P, Rb,Cs, Li, Sn and Be, and extreme depletion in Sr, Ba, Zr and REE.It is highly sodic and strongly peraluminous. The micrograniteoverall is interpreted as a mixture of two components: a crystalmush injected from below (seen in narrow dykes intersected duringdrilling, composed of quartz, albite and phengite) and interpretedas ‘feeders’, overprinted by a second highly evolvedcomponent dominated by Li, F, P (Rb, Cs, Be, Sn, Nb, Ta, etc.)considered as a ‘lubricant’ medium for the ascendingmush and occasionally quenched (quartz, albite, skeletal lepidoliteand amblygonite). This second component has the mineralogicaland chemical characteristics of rare-element pegmatites. Allthese petrological characteristics are magmatic. Only a fewnarrow cross-cutting veinlets with quartz, K-feld-spar and F-pooramblygonite are considered as fluid derived. A model of crystallizationin successive steps is proposed where concentration in fluxingagents (F, Li, P, etc.) is progressively enhanced up to saturationwith the crystallization of magmatic lepidolite and amblygonite. KEY WORDS: petrogenesis; microgranite; pegmatite; volatiles; Portugal ^*Corresponding author.     

In situ analyses of micas in the Yashan granite,South China: Constraints on magmatic and hydrothermal evolutions of W and Ta–Nb bearing granites

Most rare-metal granites in South China host major W deposits with few or without Ta–Nb mineralization. However, the Yashan granitic pluton, located in the Yichun area of western Jiangxi province, South China, hosts a major Nb–Ta deposit with minor W mineralization. It is thus important for understanding the diversity of W and Nb–Ta mineralization associated with rare-metal granites. The Yashan pluton consists of multi-stage intrusive units, including the protolithionite (-muscovite) granite, Li-mica granite and topaz–lepidolite granite from the early to late stages. Bulk-rock REE contents and La/Yb ratios decrease from protolithionite granite to Li-mica granite to topaz–lepidolite granite, suggesting the dominant plagioclase fractionation. This variation, together with increasing Li, Rb, Cs and Ta but decreasing Nb/Ta and Zr/Hf ratios, is consistent with the magmatic evolution. In the Yashan pluton, micas are protolithionite, muscovite, Li-mica and lepidolite, and zircons show wide concentration ranges of ZrO₂, HfO₂, UO₂, ThO₂, Y₂O₃ and P₂O₅. Compositional variations of minerals, such as increasing F, Rb and Li in mica and increasing Hf, U and P in zircon are also in concert with the magmatic evolution from protolithionite granite to Li-mica granite to topaz–lepidolite granite. The most evolved topaz–lepidolite granite has the highest bulk-rock Li, Rb, Cs, F and P contents, consistent with the highest contents of these elements and the lowest Nb/Ta ratio in mica and the lowest Zr/Hf ratio in zircon. Ta–Nb enrichment was closely related to the enrichment of volatile elements (i.e. Li, F and P) in the melt during magmatic evolution, which raised the proportion of non-bridging oxygens (NBOs) in the melt. The rims of zoned micas in the Li-mica and topaz–lepidolite granites contain lower Rb, Cs, Nb and Ta and much lower F and W than the cores and/or mantles, indicating an exotic aqueous fluid during hydrothermal evolution. Some columbite-group minerals may have formed from exotic aqueous fluids which were originally depleted in F, Rb, Cs, Nb, Ta and W, but such fluids were not responsible for Ta–Nb enrichment in the Yashan granite. The interaction of hydrothermal fluids with previously existing micas may have played an important role in leaching, concentrating and transporting W, Fe and Ti. Ta–Nb enrichment was associated with highly evolved magmas, but W mineralization is closely related to hydrothermal fluid. Thus these magmatic and hydrothermal processes explain the diversity of W and Ta–Nb mineralizations in the rare-metal granites.     

Some High—P—Subtype and Low—P—Subtype F—Rich Granites in South China

The F-rich granites in South CHina could be distinguished as the high-P subtype and the low-P subtype according to their P2O5 contents.There are obvious differences in chemical composition of these two subtypes,The high-P subtype is strongly peraluminous and characterized by low silica and very low REE contents,while the low-P subtype is weakly peraluminous and characterized by high silica and very high REE contents.There are also some differences in chmical compositions of feldspars and micas for these two subtypes,The phosphorus of the high-P subtype mainly appears to be in the feldspar structure as PAlSi-2 substitution or subordinately in amblygonite as an accessory mineral,while the phosphorus of the low-P subtype is mainly in apatite and other phosphate minerals.     

Uranium mineralization in the muscovite-rich granites of the Shalatin region, Southeastern Desert, Egypt

1INTRODUCTION THELATEPRECAMBRIANGRANITOIDSOFTHEARABONU BIANSHIELDINEGYPTWEREEXPOSEDBYEARLYTOMIDDLE TERTIARYUPLIFTANDENSUINGEROSIONDURINGTHEREDSEA RIFTINGEVENT(GREENBERG,1981).THEREAREANUMBER OFEFFECTIVEANDRELATIVELYSUCCESSFULSCHEMESFORTHE CLASSIFICATIONOF…     

湘西南猫儿界花岗斑岩锆石U-Pb年代学、地球化学特征及其地质意义

文章对苗儿山—越城岭地区西北侧猫儿界花岗斑岩开展了锆石U-Pb年代学、岩石地球化学和Nd同位素研究,探究了岩体的形成时代、成因类型及源区性质。三件花岗斑岩样品LA-ICP-MS 锆石U-Pb定年给出的206Pb/238U加权年龄分别为824.3±4.5 Ma、825.4±4.1 Ma和826.8±4.8 Ma,表明猫儿界岩体属新元古代岩浆活动的产物。猫儿界花岗斑岩具有高硅、铝饱和特征,富集Cs、Rb、U、K 等大离子亲石元素和 Th、Hf 等高场强元素,明显亏损Ba、Sr、Ti等元素。球粒陨石标准化稀土配分曲线呈右倾形,并具明显的Eu负异常（δEu=0.37~0.43）。岩体的εNd(t)值为-6.3~-8.7,TDM2 (Nd)值为 2.00~2.20 Ga,表明岩体由老的地壳物质部分熔融形成。在猫儿界岩体三个定年样品中发现了10颗年龄在852~861 Ma的继承锆石颗粒,加权平均年龄为856.3±7.4 Ma, 说明在苗儿山—越城岭地区可能存在~856 Ma的岩浆岩,推测猫儿界岩体在形成过程中可能有~856 Ma的岩浆物质的卷入。     

Behavior of accessory phases and redistribution of Zr,REE, Y,Th, and U during metamorphism and partial melting of metapelites in the lower crust: an example from the Kinzigite Formation of Ivrea-Verbano,NW Italy

This study is aimed at understanding the behavior of monazite, xenotime, apatite and zircon, and the redistribution of Zr, REE, Y, Th, and U among melt, rock-forming and accessory phases in a prograde metamorphic sequence, the Kinzigite Formation of Ivrea-Verbano, NW Italy, that may represent a section from the middle to lower continental crust. Metamorphism ranges from middle amphibolite to granulite facies and metapelites show evidence of intense partial melting and melt extraction. The appearance of melt controls the grain size, fraction of inclusions and redistribution of REE, Y, Th, and U among accessories and major minerals. The textural evolution of zircon and monazite follows, in general, the model of Watson et al. (1989). Apatite is extracted from the system dissolved into partial melts. Xenotime is consumed in garnet-forming reactions and is the first source for the elevated Y and HREE contents of garnet. Once xenotime is exhausted, monazite, apatite, zircon, K-feldspar, and plagioclase are progressively depleted in Y, HREE, and MREE as the modal abundance of garnet increases. Monazite is severely affected by two retrograde reactions, which may have consequences for U-Pb dating of this mineral. Granulite-grade metapelites (stronalites) are significantly richer in Ti, Al, Fe, Mg, Sc, V, Cr, Zn, Y, and HREE, and poorer in Li, Na, K, Rb, Cs, Tl, U, and P, but have roughly the same average concentration of Cu, Sr, Pb, Zr, Ba, LREE, and Th as amphibolite-grade metapelites (kinzigites). The kinzigite-stronalite transition is marked by the sudden change of Th/U from 5–6 to 14–15, the progressive increase of Nb/Ta, and the decoupling of Ho from Y. Leucosomes were saturated in zircon, apatite, and (except at the lowest degree of partial melting) monazite. Their REE patterns, especially the magnitude of the Eu anomaly, depend on the relative proportion of feldspars and monazite incorporated into the melt. The presence of monazite in the source causes an excellent correlation of LREE and Th, with nearly constant Nd/Th ≈ 2.5–3. The U depletion and increase in Th/U characteristic of granulite facies only happens in monazite-bearing rocks. It is attributed to enhancement of the U partitioning in the melt due to elevated Cl activity followed by the release of a Cl-rich F-poor aqueous fluid at the end of the crystallization of leucosomes. Halide activity in partial melts was buffered by monazite and apatite. Since the U (and K) depletion does not substantially affect the heat-production of metapelites, and mafic granulites maintain similar Th/U and abundance of U and Th as their unmetamorphosed equivalents, it seems that geochemical changes associated to granulitization have only a minor influence on heat-production in the lower crust.     

Geochemistry of the Sweetwater Wash Pluton,California: Implications for “anomalous” trace element behavior during differentiation of felsic magmas

Field relations, mineralogy and major and trace element data for the very felsic, peraluminous Sweetwater Wash pluton establish a differentiation sequence dominantly controlled by fractional crystallization processes. Elements Ba and Sr show depletion by factors of 50–60X from the earliest granite unit analyzed to the late-stage pegmatites and aplites. The strong Ba depletion is largely due to the partitioning behavior of this element in K-feldspar, while the Sr depletion is due to the combined effects of the two feldspars. The 4-fold increase in Rb during crystallization is also predictable from mineral/ melt partition coefficients.Coefficients for the light rare-earth elements (LREE) in major mineral species predict that these elements should behave incompatibly during crystallization and increase with fractionation. In fact, the LREE abundances decrease by a factor of 10–20X during crystallization. This anomalous behavior is commonly observed in felsic plutonic and volcanic sequences. In the Sweetwater Wash pluton monazite occurs in minute quantities, but it is sufficiently abundant to govern the partitioning of LREE and Th during crystallization. Petrographic observations indicate that monazite was on the liquidus throughout most of the crystallization. Analyses of silicate mineral separates suggest that the monazite contains more than 75% of the LREE in the whole rocks.Fractionation of REE-rich accessories (in particular monazite) from felsic magmas may be the general cause of REE depletion during differentiation of these melts. Monazite can easily be mistaken for zircon and, because it typically contains 50% LREE, extremely minute and easily overlooked quantities of monazite can control LREE abundances.     

桂北油麻岭钨矿区成矿岩体的年代学、地球化学及其地质意义

油麻岭钨矿位于桂北苗儿山复式岩体最南缘,矿化类型具有多样性,其中外接触带似层状矽卡岩型白钨矿是矿区最 重要的矿床类型。本文对矿区成矿母岩中- 细粒二云母花岗岩进行了锆石U-Pb 年代学和岩石地球化学的研究。LA-ICP-MS 锆石U-Pb 年龄为212~215 Ma,属印支期岩浆活动的产物。地球化学分析显示,花岗岩具有高硅（SiO2=73.73% ~78.68%）、 富碱（ALK=6.99%~8.36 %）、贫Ca（CaO=0.13%~0.96%）、贫Ti（TiO2=0.05%~0.27%）、弱过铝- 强过铝质（ACNK=1.03~1.28）的特征,稀土元素总量偏低（ΣREE=61.39×10-6~161.22×10-6）,富集Rb 和Cs 大离子亲石元素及Th,U,Ta 等高场强元素,富成矿元素W （平均含量6.55×10-6）,贫Ba 和Sr,强烈的Eu亏损（δEu=0.04~0.20）。岩石学和地球化学特征表明,成矿母岩与南岭地区典型的高分异S 型花岗岩相似。该岩体具备为钨矿的形成提供物源的能力。