杨冲金红石矿床地质特征

位于河南新县的杨冲金红石矿床。主矿体长981m、最厚处225m、延深大于189m。矿石类型包括角闪石石榴石斜长石型片麻状、斜长石绿帘石型块状、石榴石角闪石型块状及角闪石石榴石型块状4种,以第1、3、4种为主,各类矿石分布于同一矿体的不同部位,矿石品位一般2.20%～5.88%。矿床规模属大型。矿石原岩为富钛高铁基性侵入岩,成岩过程中钛进一步富集;矿床发生了两次变质作用,第一次变质相属角闪岩相-榴闪岩相,第二次属角闪岩相,均与成矿关系密切;成矿后,微弱的热液活动使金红石进一步有所富集。从大地构造特征等分析,应有良好成矿远景。     

湖北枣阳大阜山镁铁/超镁铁杂岩体与金红石矿床成因

湖北省北部枣阳市境内的大阜山镁铁/超镁铁杂岩体主要由未变质的纯橄岩和橄长岩组成,伴生变质的石榴石角闪石岩、石榴石钠黝帘石角闪石岩和角闪石钠黝帘石岩.杂岩体的围岩为大理岩.该岩体中的金红石矿床产于变质的石榴石角闪石岩或蚀变的石榴石角闪石岩中.橄长岩中锆石SHRIMP U-Pb同位素定年结果表明镁铁/超镁铁质岩体的成岩年龄约为600Ma.变质的岩石和未变质的岩石几乎具有完全相同的地球化学特征,表明前者的原岩应为橄长岩,整个岩体是一个分异的镁铁/超镁铁侵入体.金红石赋存于角闪石解理中等岩相特征表明矿床的含矿岩石就是石榴石角闪石岩,不是由石榴石辉石岩退变质形成的;且其中的石榴石为钙铁榴石,不是富镁、富铝的与高压/超高压作用有关的石榴石.金红石矿床的形成和岩体的局部变质应该与由北向南的近水平推覆构造有关,动力变质作用提供的热和流体,结合推覆过程中的变形作用,导致围岩大理岩和镁铁质岩体发生交代作用,形成石榴石角闪石岩和金红石矿床.     

金红石高-超高压变质成矿作用的几个问题

通过岩石及矿物晶体化学特征的计算,试图解决“为什么高-超高压变质作用利于金红石形成”的三方面内容:在高-超高压变质基性岩中,金红石普遍出现(即使在岩石全钛含量很低情况下)、基本不出现(或很少出现)钛铁矿、榍石、磁铁矿及赤铁矿等非金红石钛矿物及铁质矿物;石榴石和绿辉石“分流”的钛是极其有限的;以及从低压到高压,形成金红石粒度有逐渐变粗的趋势等问题。     

包古图斑岩铜矿床的钛矿物特征及其成因意义

在大量薄片鉴定的基础上,本文对包古图斑岩铜矿的钛矿物组合特征及其形成机制进行了研究。主要钛矿物为榍石、钛铁矿和金红石。其中榍石在成岩期和成矿期均有形成,但主要见于成矿期的钾化阶段,与钾长石、黑云母共生;在后期的青盘岩化和沸石化阶段也有出现,但含量相对较少。成岩期的钛铁矿很少见,成矿期各蚀变阶段均有分布,但最常见于钾化阶段。金红石仅见于成矿期,钾化阶段早期可与钾长石、黑云母、石英等共生,还见有被榍石包裹的细粒金红石,青盘岩化阶段亦有形成,与绿泥石共生。这些钛矿物最常出现于黑云母颗粒内部或其附近,这可能是斑岩型矿床的特征之一。榍石SiO₂和CaO含量与理论值接近,TiO₂偏低;钛铁矿均含锰,MnO含量1.97%~4.49%,还见有锰钛铁矿;金红石含有一定量的SiO₂和FeO^T,个别颗粒还含有少量Al₂O₃、MgO和P₂O₅。钛矿物组合特征表明包古图含矿斑岩为I型,形成于较高氧逸度环境,侵位深度不大。     

西准噶尔克拉玛依蛇绿混杂岩中的石榴角闪岩

本文报道在准噶尔地区发现的石榴角闪岩,该岩石产在克拉玛依蛇绿混杂岩带的百口泉地区.石榴角闪岩主要由钙质角闪石、富钠斜长石和黝帘石组成,含少量钛铁矿、绿帘石、绿泥石、榍石、石榴石、普通辉石、金红石、磷灰石、钠长石、石英和锆石.石榴石中常包裹磷灰石、金红石、钛铁矿、石英和锆石.黝帘石 富钠斜长石组合中出现少量钙铝榴石残余.百口泉石榴角闪岩中石榴石的化学组成特征以及其中出现的金红石-钛铁矿-磷灰石-石英-锆石包体组合说明,该岩石不是异剥钙榴岩退变质的产物,而是榴辉岩退变的产物(辅助证据包括二辉橄榄岩中发育的辉石出溶结构和辉石塑性变形特征).百口泉石榴角闪岩至少记录了四个阶段:石榴石-单斜辉石-金红石-磷灰石-石英-锆石组成的阶段Ⅰ(可能为榴辉岩相),普通辉石-钛铁矿-磷灰石-角闪石组成的退变阶段Ⅱ,角闪石-斜长石-榍石-钛铁矿构成的阶段Ⅲ(角闪岩相),以及绿帘石-石英-绿泥石构成的绿片岩相变质阶段Ⅳ.尽管上述演化历史存在一些不确定性,石榴角闪岩的发现为深入研究西准噶尔地区古生代洋壳俯冲带的性质及其演化过程提供了新的物质基础.     

班公湖-怒江缝合带西段洞错石榴石麻粒岩岩石学特征及其构造意义

班公湖-怒江缝合带是青藏高原中部一条重要的构造边界,将北部的羌塘地块与南部的拉萨地块分隔开,当前对班公湖-怒江洋壳的俯冲过程知之甚少,本文报道班公湖-怒江缝合带西段洞错地区的石榴石麻粒岩,将有助于提升班公湖-怒江缝合带构造演化过程的认识。石榴石麻粒岩呈5.0~_10mm的透镜体产出于斜长角闪岩内,后者呈构造岩片产出于班公湖-怒江缝合带内,与超基性岩片呈断层接触。石榴石麻粒岩的石榴石呈变斑晶产出,具有不规则的成分环带,石榴石核部成分较均匀,以富Ca和Mg,贫Fe和Mn为特征,石榴石边缘及内部裂隙成分则与之相反,富Fe和Mn,与绿泥石和黝帘石组成的细脉共生,反映了石榴石遭受后期流体的交代作用。单斜辉石为透辉石,在其内部发现早期进变质阶段的细小石榴石与角闪石颗粒,石榴石粒径_10μm,该石榴石相对富Fe和Mn,贫Ca和Mg。角闪石均为钙质系列的角闪石,早期角闪石以相对富Na和Fe~(3+),含有微量Ba,而与晚期角闪石区分开。早期角闪石常产出于石榴石和透辉石变斑晶内部,脱水熔融生成富Ca、贫Fe~(3+)和Na的透辉石和以钠长石为主的熔融囊体,囊体内部发育斜长石和富Ba冰长石的包体/出溶体。晚期角闪石常与斜长石呈细小的后成合晶产出于石榴石边部或呈变斑晶产出于基质之中,表明斜长角闪岩系石榴石麻粒岩退变质的产物。此外,金红石斑晶常变成细粒、不规则的贫Al榍石和钛铁矿,基质中有相对富Al榍石产出。因此该麻粒岩进变质阶段矿物组合由早期石榴石(Grt__1)、早期角闪石(Amp_1)、相对富Al的榍石(Spn_1)等矿物组成。峰期矿物组合包括:核部石榴石(Grt2)+透辉石+斜长石(Pl_1)+石英+金红石+富Na和Ba的熔体,采用传统温/压计估算此峰期矿物组合形成条件为870℃、11.7kbar。退变质矿物组合有:边部石榴石(Grt3)+晚期贫Na和Fe~(3+)的角闪石(Amp_1)+黝帘石+绿泥石+斜长石(Pl_2)+白云母+贫Al榍石(Spn2)+钛铁矿。岩相学观察与地球化学示踪、变质温压估计表明洞错石榴石麻粒岩系热洋壳俯冲的产物,为前人提出的"班公-怒江洋盆包含次级小洋盆"之观点提供了变质岩石学的证据。从峰期到退变质阶段,角闪石的Fe~(3+)含量明显下降,铁铝榴石含量明显升高,指示该麻粒岩经历了还原反应,早期角闪石脱水熔融时被还原,生成了高氧逸度的埃达克质岩浆,促进了Cu、Au等成矿元素从俯冲热洋壳的活化与迁移至弧岩浆之中,因此本文的研究提供了一个探讨俯冲热洋壳与上覆地幔楔之间化学反应的研究案例,这有助于理解班公-怒江成矿带内众多斑岩型铜、金矿床的形成。     

西南天山超高压变质带的两类石榴角闪岩

角闪岩是西南天山超高压变质带变基性岩的常见岩石类型之一.野外关系和矿物反应结构表明,大多数角闪岩是由榴辉岩或蓝片岩受到不同程度的钠长绿帘角闪岩相退变质叠加形成的.但对于一些平衡结构发育良好且孤立产出的角闪岩类型（如石榴角闪岩）仍缺乏系统的岩石学研究.本次从岩相学、矿物成分以及热力学模拟几个方面对哈布腾苏河下游地区超高压带内不含钠长石的石榴角闪岩开展了详细的工作.这些石榴角闪岩的主要矿物为绿色角闪石（钙质-钠钙质闪石）、帘石（黝帘石-绿帘石）和石榴石,三者总体积占80%~90%,明显有别于大多数由榴辉岩退变而成的含有钠长石变斑晶的石榴角闪岩.虽然这些角闪岩化学成分十分相近,都具有富钙贫钠和高的Mg/（Mg+Fe）比值,但在结构、构造和矿物组成等方面存在显著差异,据此将它们划分为两类.第一类角闪岩基质中不含石英,保存在变斑晶中的少量残余矿物组合为石榴石+绿辉石+硬柱石+蓝闪石+金红石,指示峰期硬柱石榴辉岩相变质条件,富钛矿物全部为金红石.第二类角闪岩强烈面理化,面理由绿色角闪石、绿帘石和绿泥石以及条带状石英集合体构成.石榴石粒度呈双峰式分布,粗粒比细粒低钙低锰.基质和包体中均未发现高压变质特征矿物绿辉石和蓝闪石.富钛矿物以榍石为主,金红石和钛铁矿仅存在于个别石榴石中.两类角闪岩的石榴石成分具有较大区分度,前者的钙含量较高而镁含量较低.P-T视剖面计算显示它们的峰期条件为480~520 ℃,30~33 kbar,均达到超高压范围,与哈布腾苏河下游及以西地区的榴辉岩相似,表明西南天山超高压变基性岩构成沿中天山南缘断裂延伸数十千米的独立地质单元,不存在所谓的俯冲隧道混杂现象.      

某低品位铁矿中铁钛元素赋存状态研究

以电子探针(EPMA)为主要研究手段,结合常规化学分析、化学物相分析、透反射显微镜研究,对黔西北某地低品位铁矿中铁—钛的赋存状态进行了详细研究。研究结果表明,矿石中铁主要以褐铁矿形式存在,少量以赤铁矿产出。载铁矿物与粘土矿物常常混杂出现,分布不均,团块大小差异也大,矿物间的嵌布关系复杂;钛在矿石中一是以微细粒的独立矿物金红石、锐钛矿、钛铁矿与脉石矿物相互混杂分布,另一种则是蚀变残留于褐铁矿中类质同象的钛。根据铁、钛赋存特征研究结果,对该矿石提出了"分散—絮凝—磁选"分离预富集铁—钛矿物、"直接还原法"实现铁钛分离的工艺建议。     

青龙山榴辉岩的退变质显微结构及相关的物质迁移——南苏鲁榴辉岩退变质过程中流体活动的证据

对南苏鲁青龙山榴辉岩的扫描电子显微镜及光学显微镜的详细观察表明，其峰期矿物组合为石榴石 绿辉石Ⅰ 蓝晶石 金红石( 柯石英)，基本无含水矿物，并被第二期矿物(或组合)逐步替代，形成后成合晶或冠状体假像，即：绿辉石Ⅰ→绿辉石Ⅱ 钠长石 铁氧化物后成合晶，金红石→金红石 钛铁矿，蓝晶石→钠云母。第二期矿物又被第三期矿物(组合)替代：绿辉石Ⅱ( 钠长石 铁氧化物)→角闪石( 斜长石 铁氧化物)，石榴石→韭闪石 铁氧化物。绿帘石与石英是最晚期流体沿微裂隙活动的产物。详细的矿物成分分析及成分迁移估算结果显示，早期后成合晶的形成过程产生多余的Fe、Mg、Na，但消耗部分Ca、Si。产生的Mg、Fe迁移到石榴石边部，引发石榴石内部的(Mg，Fe)／Ca交换，在石榴石颗粒中形成向边部Ca降低、Mg和Fe升高的成分环带。交代产生的Ca被后成合晶消耗，而后成合晶产生的Na被替代蓝晶石的钠云母消耗。在退变质作用晚期，更多流体进入榴辉岩，引发流体渗滤交代反应，无水的早期后成合晶被含水后成合晶(角闪石 斜长石 铁氧化物)替代，同时在石榴石边部形成角闪石 少量铁氧化物反应边。成分迁移估算显示，上述两个过程的成分变化具有一定程度的耦合性。矿物反应曲线、THERMOCALC计算确定的P-T轨迹显示，青龙山榴辉岩的退变质过程主要发生在高压条件(低地温梯度)下，明显不同于北苏鲁地区榴辉岩。这种热演化特点的差异暗示南北苏鲁超高压变质块体可能具有不同的回返历史。     

辽宁弓长岭铁矿床二矿区类矽卡岩的岩石矿物学特征

辽宁弓长岭铁矿床二矿区是我国最重要的鞍山式沉积变质型富铁矿床.不同于鞍山-本溪地区其他贫铁矿床,弓长岭铁矿二矿区富铁矿体的附近分布有大量的类矽卡岩,这些类矽卡岩与富铁矿体具有密切的成因联系.本文在野外和岩相学研究的基础上,选择弓长岭二矿区类矽卡岩的岩相学、矿物学、矿物化学特征进行了研究.结果表明:类矽卡岩可分为石榴石岩、绿泥石岩、含石榴石绿泥石岩、含磁铁矿阳起石岩四种类型;类矽卡岩矿物中石榴石端员组分以铁铝榴石为主,角闪石属于钙角闪石系列中的透闪石,绿泥石属于蠕绿泥石.类矽卡岩和富铁矿是由热液交代改造磁铁贫矿形成的,二者是同一期热液活动的产物.     

地震预报路在八方

中国处于地震多发区,地震预报、预防工作显得尤为重要,通过建立《地震监测预报法》,提高全民防震防灾意识,检测现有房物抗震等级,地震局系统提升地震预报预测职能和工作力度;设置预防及减灾、救灾的机关或常设机构等10项措施,加大地震预防预报能力,减少地震带来的损失。     

Evolution of Hutti-Maski greenstone belt of the Eastern Dharwar Craton: Evidence for metamorphic and hydrothermal phases from the Hira-Buddini deposit,Raichur district,Karnataka, India

The Hira-Buddini gold deposit is located along the steeply dipping ENE trending sheared contact of felsic and mafic rocks of strike length of about 600 m with mylonitic foliation parallel to the S1 schistosity in amphibolites. Second-generation open folds with axial planes (S2) marked by fractures that are often filled by later calcite veins are observed in surface and underground exposures. Garnetiferous amphibolites occur in patches on the footwall side of the shear in the western part of the deposit. This rock shows garnet porphyroblasts, coarse second-generation hornblende and large grains of biotite that grow over an early S1 fabric which is made up of early hornblende, plagioclase, ilmenite and retrograde first-generation chlorite. Second-generation hornblende and biotite grains make high angles to S1 schistosity and are sub-parallel to S2. Late hydrothermal alteration is marked by an albite-epidote-chlorite-zoisite assemblage. Geothermometric estimates based on garnet-biotite, and garnet-hornblende pairs, as well as Ti in biotite, show that temperatures during D2 deformation that led to the growth of the porphyroblasts were \(530{\pm }20^{\circ }\hbox {C}\). The fabric and mineralogy of the rock indicate that porphyroblastic growth of garnet, hornblende and biotite was preceded and succeeded by stages of hydrothermal alteration. Primary gold mineralization is inferred to be associated with the early stage of hydrothermal ingress.     

弓长岭鞍山群太古代基底岩石特征

弓长岭鞍山群呈北西至南东方向分布，位于中朝陆块东端，该群各类型岩石构成华北陆块古老的变质结晶基底。文中详细地记述了岩浆岩及混合岩、硅质板岩和长英质变粒岩、交超基性岩、交基性火山岩、变泥质岩、铁矿床、变辉长辉绿岩岩墙群的岩石特征和产出特征及成岩时代。本区为低压区域浅变质类型，演化与成岩时代约在太古代的中、晚期(3400～2500Ma)。     

华北克拉通中部带云中山石榴斜长角闪岩变质演化及其构造意义

云中山地体位于华北克拉通中部造山带中部,是衔接吕梁地体和五台-恒山地体的关键位置.确定云中山地体的变质作用演化历史可为深入理解吕梁-云中山-五台-恒山地区的整体地质过程提供重要限定.对云中山石榴斜长角闪岩开展了详细的岩石学、相平衡模拟和锆石年代学研究.两个代表性样品均具有顺时针变质P-T-t轨迹,峰期阶段位于金红石稳定域,温压条件分别为0.96±0.11 GPa/720±8.0℃（L1903）和1.26±0.08 GPa/756±14.0℃（L1906）;峰期后发生降压作用,金红石转变成钛铁矿,石榴石边部生长斜长石（+普通角闪石）冠状边,普通角闪石转变成镁铁闪石;晚期阶段以冷却为主,石榴石的边部出现少量绿泥石交代.对两个样品的岩石组构和化学成分对比表明,石榴斜长角闪岩的部分熔融受全岩成分影响,岩石贫硅钠而富铁镁钛时难熔,反之则易熔.样品变质锆石的U-Pb定年结果为1 928~1 806 Ma.这些锆石相对富集重稀土,利用锆石Ti温度计计算的结晶温度为520~680℃,与岩石的冷却温度相近,因此所获年龄应代表退变冷却时代.吕梁-云中山-五台-恒山地区的整体地质特征对比表明,云中山地体的岩石-地层组成和变质作用演化与五台-恒山地体非常相似,记录了古元古代晚期的碰撞造山事件.      

Metamorphic evolution of oceanic gabbros: recrystallization from subsolidus to hydrothermal conditions in the MARK area (ODP Leg 153)

The 117.38 m of gabbroic core drilled during the Ocean Drilling Program (ODP) Leg 153 at Sites 921 to 924 in the Mid-Atlantic Ridge (MAR) between 23 °N and the Kane Fracture Zone, exhibits a remarkable primary compositional heterogeneity, such as magmatic layering, intrusive contacts and late magmatic veining, which express a succession of magmatic events. Textural indicators suggest that the cooling of the crystal mush occurred in a dynamic environment, with infiltration of progressively evolved liquids. Magmatic features include random shape fabric and magmatic lamination; the subsequent deformational overprint occurred in subsolidus conditions. The ductile deformation, generally concentrated in discrete domains of the gabbro, is associated with continuous re-equilibration of the metamorphic assemblages of (1) olivine + clinopyroxene + orthopyroxene + plagioclase + ilmenite + Ti-magnetite, (2) olivine + clinopyroxene + plagioclase + ilmenite + Ti-magnetite + red hornblende. At lower temperatures brittle deformation prevails and subsequent fractures control the development of metamorphic assemblages: (3) clinopyroxene + plagioclase + red brown hornblende + Ti-magnetite + magnetite (?) + ilmenite, (4) plagioclase + brown hornblende + Ti-magnetite + magnetite + hematite + titanite ± Ti-oxide, (5) plagioclase + green hornblende + magnetite + titanite, (6) plagioclase + actinolite + chlorite + titanite + magnetite, (7) albite + actinolite + chlorite + prehnite ± epidote ± titanite and (8) albite + prehnite + chlorite ± smectite. Assemblages 1 to 8 express increasing water/rock ratios and decreasing degrees of recrystallization.

During the ductile phase, red hornblende is stable and its abundance increases with deformation intensity, possibly as an effect of the introduction of hydrous fluids. During the brittle phase, water diffusion controls the development of the fracture-filling mineral assemblages and re-equilibration of the adjacent rock; temperatures decrease further, as demonstrated by mineral zoning and incompletely re-equilibrated assemblages. The lowest temperatures correspond to the development of hydrothermal assemblages.

Compared with oceanic gabbros from fast-spreading transform environments, high-temperature ductile phases (granulite and amphibolite) are well developed, whereas brittle phases are widespread, as microcracks, prevalent on fracturing associated with discrete veins.     

The Garnet+Hornblende Isograd in Calcic Schists from an Andalusite-Type Regional Metamorphic Terrain, Panamint Mountains, California

Calcic schists in the andalusite-type regional metamorphic terrainin the Panamint Mountains, California, contain the low-varianceassemblage quartz+epidote+muscovite+biotite+calcic amphibole+chlorite+plagioclase+spheneat low grade. Near the sillimanite isograd, chlorite in thisassemblage is replaced by garnet. The low variance in many calcicschists allows the determination of the nature of the reactionthat resulted in the coexistence of garnet+hornblende. A graphicalanalysis of the mineral assemblages shows that the reactioncan not be of the form biotite+epidote+chlorite+plagioclase+quartz=garnet+hornblende+muscovite+sphene+H₂Obecause garnet+chlorite never coexisted during metamorphismand the chlorite-bearing and garnet-bearing phase volumes donot overlap. The compositions of the minerals show that withincreasing grade amphibole changed from actinolite to pargasitichornblende with no apparent miscibility gap, the partitioningof Fe and Mg between chlorite and hornblende changed from K_D(Mg/Fe, chl&amp) < 1 to K_D > 1, the partitioning betweenbiotite and hornblende changed from K_D (Mg/Fe, bio/amp) <1 in chlorite-zone samples to K_D > 1 in garnet + hornblende-zonesamples, and the transition to the garnet-bearing assemblageoccurred when the composition of plagioclase was between An₅₅and An₈₀. Both the graphical analysis and an analytical analysisof the compositions of the minerals using simplified componentsderived from the natural mineral compositions indicate thatat the garnet+hornblende isograd the composition of hornblendewas colinear with that of plagioclase and biotite, as projectedfrom quartz, epidote, muscovite, and H₂O. During progressivemetamorphism, chlorite+biotite+epidote+quartz continuously brokedown to form hornblende+muscovite+sphene until the degeneracywas reached. At that point, tie lines from hornblende couldextend to garnet without allowing garnet to coexist with chlorite.Thus, the garnet+hornblende isograd was established throughcontinuous reactions within the chlorite-grade assemblage ratherthan through a discontinuous reaction. In this type of isograd,the low-grade diagnostic assemblage occurs only in Mg-rich rocks;whereas the high-grade assemblage occurs only in Fe-rich rocks.This relation accounts for the restricted occurrence of garnet+hornblendeassemblage in low-pressure terrains. In Barrovian terrains,garnet+chlorite commonly occurs, and the first appearana ofgarnet+hornblende can simply result from the continuous shiftof the garnet+chlorite tie line to Mg-rich compositions.     

江汉平原主要河流沉积物重矿物特征与物源区岩性的响应

通过对江汉平原主要河流沉积物的重矿物组合、特征矿物以及能够反映沉积物稳定状况、物源及成熟度的重矿物特征指数(ATi,GZi和ZTR)进行对比分析,发现在江汉平原范围内,长江和汉江及其长江主要支流的沉积物中重矿物特征具有显著的差异。长江的重矿物组合模型为：  锆石+绿帘石+辉石+绿泥石+金属矿物,特征矿物是锆石和辉石;   汉江的重矿物组合模型为：  绿帘石+角闪石+石榴石+绿泥石+金属矿物,特征矿物是角闪石、石榴石;   另外,清江、漳河、沮水和玛瑙河的重矿物组合及特征矿物也都完全不同。而且各水系的沉积物的重矿物特征与其源区的岩性分布显示出极好的相关性。研究表明在江汉平原利用重矿物特征及组合模型来进行物源示踪的方法开展水系演化研究是可行的。     

Coexisting chloritoid-staurolite from the Sillimanite (fibrolite) zone,Sini, district Singhbhum,India

Microprobe analyses of the minerals from an unusual chloritoid-staurolite-garnet (+ muscovite + quartz + ilmenite) assemblage from the sillimanite (fibrolite) zone of Sini, India are presented and the petrological significance of the paragenesis is discussed. The X Mg in the different minerals from the chloritoid-staurolite-bearing rock varies in the order, muscovite > chlorite > chloritoid > staurolite > garnet > ilmenite, and from the associated sillimanite-bearing schists: muscovite > biotite > staurolite > garnet rim > garnet core > ilmenite. A graphical representation of the mineral compositions in an AFM projection displays a consistent topology if the effects of non-AFM components such as Zn in the staurolite and Mn in the garnet are taken into account. Petrographic and mineralogical data are consistent with a prograde formation of the chloritoid-staurolite-garnet assemblage. It is suggested that the paragenesis has been formed at similar PT conditions to the associated sillimanite (fibrolite)-staurolite-garnet-mica schists. These conditions are estimated to be 600–625°C/6±0.5 Kb.     

Superposition of replacements in the mafic granulites of the Jijal complex of the Kohistan arc, northern Pakistan: dehydration and rehydration within deep arc crust

A deep-level crustal section of the Cretaceous Kohistan arc is exposed in the northern part of the Jijal complex. The occurrence of mafic to ultramafic granulite-facies rocks exhibits the nature and metamorphic evolution of the lower crust. Mafic granulites are divided into two rock types: two-pyroxene granulite (orthopyroxene+clinopyroxene+plagioclase±quartz [1]); and garnet–clinopyroxene granulite (garnet+clinopyroxene+plagioclase+quartz [2]). Two-pyroxene granulite occurs in the northeastern part of the Jijal complex as a relict host rock of garnet–clinopyroxene granulite, where the orthopyroxene-rich host is transected by elongated patches and bands of garnet–clinopyroxene granulite. Garnet–clinopyroxene granulite, together with two-pyroxene granulite, has been partly replaced by amphibolite (hornblende±garnet+plagioclase+quartz [3]). The garnet-bearing assemblage [2] is expressed by a compression–dehydration reaction: hornblende+orthopyroxene+plagioclase=garnet+clinopyroxene+quartz+H₂O↑. Subsequent amphibolitization to form the assemblage [3] is expressed by two hydration reactions: garnet+clinopyroxene+plagioclase+H₂O=hornblende+quartz and plagioclase+hornblende+H₂O=zoisite+chlorite+quartz. The mafic granulites include pod- and lens-shaped bodies of ultramafic granulites which consist of garnet hornblendite (garnet+hornblende+clinopyroxene [4]) associated with garnet clinopyroxenite, garnetite, and hornblendite. Field relation and comparisons in modal–chemical compositions between the mafic and ultramafic granulites indicate that the ultramafic granulites were originally intrusive rocks which dissected the protoliths of the mafic granulites and then have been metamorphosed simultaneously with the formation of garnet–clinopyroxene granulite. The results combined with isotopic ages reported elsewhere give the following tectonic constraints: (1) crustal thickening through the development of the Kohistan arc and the subsequent Kohistan–Asia collision caused the high-pressure granulite-facies metamorphism in the Jijal complex; (2) local amphibolitization of the mafic granulites occurred after the collision.     

内蒙古中部大黄花夕卡岩型铜多金属矿床特征

大黄花铜多金属矿位于赤峰-朝阳金多金属成矿带南部,矿化发生在燕山期正长花岗岩与石炭系酒局子组大理岩接触部位,局部构成铜（铁）矿体.夕卡岩矿物主要为石榴石、透辉石、透闪石、绿帘石、绿泥石、角闪石及阳起石,金属矿物有黄铜矿、辉铜矿、黝铜矿、斑铜矿、铜蓝及氧化次生矿物蓝铜矿、孔雀石、褐铁矿.围岩蚀变强烈,呈现清晰的蚀变分带现象,自接触带向外可分为较强的透闪石-阳起石化带,较强的透闪石-透辉石化带,弱蚀变的大理岩化带.金属元素组合特征明显,为Cu、Pb、Zn、Au、Ag组合.该铜多金属矿的形成与正长花岗岩的侵入作用有关,成矿时代为中侏罗世晚期,与朝阳-赤峰地区金多金属矿成岩成矿时代一致.