祁连山老君山砾岩的碎屑组成和源区大地构造背景

老君山砾岩是一套由砾岩和杂砂岩组成的陆相粗碎屑岩.砾岩由来自下伏基底的超镁铁岩、中-基性火山岩、硅质岩、花岗岩等碎屑组成.杂砂岩中岩屑含量大于70%,石英约10%,长石约15%.岩屑以中基性火山岩和花岗岩为主;硅质岩屑是主要的沉积岩屑.锆石、磷灰石、磁铁矿是杂砂岩中最为丰富的重矿物,同时还有铬铁矿、石榴子石、电气石、金红石、黄铁矿.这些事实说明,老君山砾岩的源区曾出露有超镁铁岩、中基性火山岩、变质岩等类型的岩石.砂岩碎屑模式和粉砂岩、泥岩的地球化学成分均表明,老君山砾岩源区为大陆边缘弧和大洋岛弧,形成于活动大陆边缘与岛弧相关的沉积盆地中.     

祁连山老君山砾岩的碎屑组成和源区大地构造背景

老君山砾岩是一套由砾岩和杂砂岩组成的陆相粗碎屑岩。砾岩由来自下伏基底的超镁铁岩、中—基性火山岩、硅质岩、花岗岩等碎屑组成。杂砂岩中岩屑含量大于70%,石英约10%,长石约15%。岩屑以中基性火山岩和花岗岩为主;硅质岩屑是主要的沉积岩屑。锆石、磷灰石、磁铁矿是杂砂岩中最为丰富的重矿物,同时还有铬铁矿、石榴子石、电气石、金红石、黄铁矿。这些事实说明,老君山砾岩的源区曾出露有超镁铁岩、中基性火山岩、变质岩等类型的岩石。砂岩碎屑模式和粉砂岩、泥岩的地球化学成分均表明,老君山砾岩源区为大陆边缘弧和大洋岛弧,形成于活动大陆边缘与岛弧相关的沉积盆地中。     

秦岭造山带泥盆系形成构造环境：来自碎屑岩组成和地球化学方面的约束

秦岭造山带中分布于商丹和勉略缝合带之间的泥盆系,发育有众多Au、Ag和Pb-Zn矿床,长期以来备受关注。对于泥盆系物源和形成环境认识始终存在不同认识。砂岩碎屑组成、碎屑重矿物、地球化学成分、砾岩组成以及古水流研究表明,北秦岭是秦岭泥盆系的主要物源区,盆地基底隆起也是泥盆系重要物源区。砂岩碎屑组成、碎屑重矿物和砾岩组成表明,泥盆系物源区曾出露有岛弧火山岩、花岗岩、变质岩及少量沉积岩、超镁铁岩。砂岩地球化学成分和砂岩碎屑模式研究表明,秦岭造山带中泥盆系主要形成于活动大陆边缘,其碎屑沉积物来自多种构造环境中的岩石单元。     

北祁连山东段海原一带海原群变质岩原岩恢复及其构造背景

对海原群的岩石组成、原岩性质和构造环境的研究表明,海原群中云母片岩、石英片岩的原岩是泥质岩、杂砂岩等,大理岩、石英岩的原岩为白云岩-灰岩、石英砂岩或硅质岩,绿片岩和角闪岩的原岩为基性火山岩或次火山岩,蛇纹岩的原岩为超镁铁质岩.变质沉积岩的形成构造环境判别结果表明,它们形成于活动大陆边缘,介于岛弧与稳定陆缘之间.变质基性火山岩主要亦介于岛弧拉斑玄武岩与板内玄武岩之间,部分显示洋脊玄武岩的特征.认为海原群形成于岛弧-弧后盆地的构造环境.     

北祁连山东段海原一带海原群变质岩原岩恢复及其构造背景

对海原群的岩石组成、原岩性质和构造环境的研究表明,海原群中云母片岩、石英片岩的原岩是泥质岩、杂砂岩等,大理岩、石英岩的原岩为白云岩-灰岩、石英砂岩或硅质岩,绿片岩和角闪岩的原岩为基性火山岩或次火山岩,蛇纹岩的原岩为超镁铁质岩.变质沉积岩的形成构造环境判别结果表明,它们形成于活动大陆边缘,介于岛弧与稳定陆缘之间.变质基性火山岩主要亦介于岛弧拉斑玄武岩与板内玄武岩之间,部分显示洋脊玄武岩的特征.认为海原群形成于岛弧-弧后盆地的构造环境.     

北祁连山东段海原一带海原群变质岩原岩恢复及其构造背景

对海原群的岩石组成、原岩性质和构造环境的研究表明,海原群中云母片岩、石英片岩的原岩是泥质岩、杂砂岩等,大理岩、石英岩的原岩为白云岩—灰岩、石英砂岩或硅质岩,绿片岩和角闪岩的原岩为基性火山岩或次火山岩,蛇纹岩的原岩为超镁铁质岩。变质沉积岩的形成构造环境判别结果表明,它们形成于活动大陆边缘,介于岛弧与稳定陆缘之间。变质基性火山岩主要亦介于岛弧拉斑玄武岩与板内玄武岩之间,部分显示洋脊玄武岩的特征。认为海原群形成于岛弧—弧后盆地的构造环境。     

北大巴山新元古代龙潭河组的源区特征：来自碎屑组成和锆石年代学的证据

沿扬子板块北缘大巴山弧形断裂出露的新元古代龙潭河组主体为一套富火山碎屑沉积岩夹原生火山碎屑岩组合。长期以来,它们以及上覆砂砾岩组合(木座组)(前人认为冰蹟岩)统被解释为扬子板块北缘新元古代陆内裂谷和被动陆缘沉积。龙潭河组岩石组合包括杂砂岩、含砾粗砂岩、砾岩、凝灰质粉砂岩夹(含砾)凝灰岩。砂岩碎屑组成研究表明,龙潭河组碎屑以火山岩岩屑和斜长石为主,少量石英,砾岩砾石主要为玄武岩、玄武安山岩/安山岩。这些特征表明物源区主要出露中、基性火山岩和富火山碎屑沉积岩,少量长英质岩石,源区大地构造背景为岛弧。本文对一套具有近源堆积特征的火山质砾岩进行了碎屑锆石LA-ICP-MS U-Pb定年分析,结果显示锆石具有两组集中年龄群,峰值分别为~770 Ma和~705 Ma,表明源区存在至少两期岩浆活动。龙潭河组砾石、岩屑和锆石较差的磨圆度和分选性共同表明它们为一套近源沉积,碎屑组成表明物源区为~705 Ma岛弧,形成于弧后环境。龙潭河组物源区岛弧构造背景的确定暗示南秦岭造山带北大巴山地区与俯冲相关的岛弧构造体制一直持续到~705 Ma。     

北祁连东段景泰地区下古生界两套砂岩微量元素和稀土元素特征及其构造意义

早奥陶世和早志留世是北祁连加里东造山带构造演化和盆地转变的关键时期。在造山带东段景泰地区,下奥陶统阴沟组和下志留统肮脏沟组两套砂岩的微量元素和稀土元素特征显示,阴沟组杂砂岩样品（Cj1和Cj3）具有最小的Eu/Eu*及最大的Th/Sc和REE,肮脏沟组杂砂岩具有较小的Eu/Eu*和较大的Th/Sc及REE;阴沟组岩屑砂岩样品（Cj13、Cj15和Cj18）具有最大的Eu/Eu*及最小的Th/Sc、REE和La/Yb。多个物源、构造背景判别图解和多元素蛛网图分析表明,阴沟组杂砂岩样品具大陆边缘的构造背景,主要物源为大陆上地壳再旋回沉积物和长英质岩石;岩屑砂岩样品为岛弧构造背景,以中基性安山质岩石为主要物源,可能受陆源物质的微弱影响。肮脏沟组杂砂岩构造背景复杂,表现出大陆岛弧、活动陆缘和被动陆缘三种环境共存的特点,受中基性火山弧物质、长英质岩石和再旋回沉积岩的混合物源的影响。两套砂岩的元素特征表明二者可能具有相似的源区。阴沟组杂砂岩源区可能为阿拉善地块南缘海原群变沉积岩或其他相似的陆源再旋回沉积物,砂岩碎屑以来自初始火山弧物质为主,以石灰沟岛弧型中基性火山岩作为其源岩最合适。阴沟组形成于初始弧后盆地环境,是岛弧活动的直接记录。肮脏沟组可能的源岩为阿拉善地块南缘海原群变沉积岩和中高等成熟度的石灰沟岛弧型火山岩及海原群岛弧型变火山岩,沉积于弧后前陆盆地,对构造环境的反映存在滞后性。     

东昆仑南缘布青山地区马尔争组物源分析及其构造背景研究

内容提要：布青山地区马尔争组复理石岩系位于东昆仑南缘,其主体是一套沉积于深海—半深海环境的浊积岩,本文研究了复理石岩系中砂岩的沉积岩石学、碎屑骨架模型及岩石地球化学特征。碎屑组分统计结果表明其砂岩类型主要为长石岩屑砂岩,石英、岩屑、长石的平均含量分别为42%、37%、21%,物源类型为切割型岛弧及再旋回造山带。马尔争组砂岩w（SiO2）含量介于50.18%～74.05%,平均值为66.69%,CIA=43～69;∑REE为59.99×10～6～171.07×10～6,∑LREE/∑HREE=6.6～8.8;LaN/YbN=6.6～10.7,LaN/SmN=3.2～4.6,δEu=0.59～1.04。砂岩地球化学特征指示马尔争组复理石岩系形成于沟弧盆系活动大陆边缘构造环境,砂岩属大陆岛弧型,物源区为北侧东昆仑地块火山～深成岩浆岛弧造山带及变质基底,源岩为长英质火山岩、同源深成侵入岩及基底变质岩,沉积盆地为俯冲杂岩外侧的古海沟环境。它间接地记录了阿尼玛卿—布青山古特提斯洋的持续扩张—向北俯冲消减—洋盆闭合的过程。     

东昆仑南缘哥日卓托地区马尔争组砂岩碎屑组成、地球化学特征与物源构造环境分析

出露于东昆仑南缘布青山构造混杂岩带内的马尔争组沉积地层,其主体为一套沉积于被动大陆边缘构造环境的大陆斜坡相深海-半深海浊积岩。利用砂岩碎屑组分统计分析及岩石地球化学特征研究,探讨物源区源岩类型及其构造环境。砂岩骨架成分统计表明马尔争组砂岩主要类型为长石岩屑砂岩且成熟度较低,砂岩碎屑骨架成分为石英、长石、岩屑,含量平均值分别为44%、21%、35%,Dickinson三角图解显示其物源类型为再旋回造山带物源区和岩浆弧物源区的混合物源。砂岩岩石地球化学特征结果显示,马尔争组砂岩样品SiO,=58.12%~72.98%,均值67.77%,REE配分曲线总体表现为右倾,∑LREE/∑HREE=6.5~12.1,δEu=0.63~0.75,Eu具弱负异常,CIA值为56说明源岩遭受初级强度风化作用,具近源沉积特征。研究结果指示马尔争组砂岩物源区构造环境为大陆岛弧,源岩性质为长英质火山岩和花岗岩类源岩且主要来源于北侧东昆仑造山带加里东期岩浆弧与变质基底,沉积盆地类型为深海半深海盆地。它是古特提斯洋北支布青山阿尼玛卿洋演化历史过程中一次重要的沉积响应。     

云南剑川-老君山新生代盆地铀矿化特征

剑川-老君山新生代盆地是以上三叠统石钟山组为基底,以新近系剑川组为主要盖层的继承性火山断陷盆地。剑川组为一套粗面岩、凝灰岩、火山角砾岩、集块熔岩、凝灰质砂岩、岩屑砂岩等组成的火山沉积岩系。研究发现,剑川-老君山盆地的铀矿化受区域性断裂及火山构造的复合控制。盆地内已发现有凝灰岩型、砂岩型、正长斑岩型、花岗斑岩型、粗面岩型和花岗伟晶岩型等6种类型的铀矿化,具有良好的找矿前景。     

西藏吉瓦地区渐新统日贡拉组物源分析及找矿意义

通过详实的野外调查和室内研究,在西藏吉瓦地区新发现了砂岩型铜矿床,赋矿层位为渐新统日贡拉组,矿床类型为层控矿床。为探讨日贡拉组砂岩的物源特征及其构造背景、查明其含矿物质来源,通过碎屑矿物定量分析、元素地球化学方法及重矿物组合分析等一系列物源分析方法对日贡拉组的物质来源进行了研究。结果显示,研究区主要岩性为岩屑砂岩,岩屑主要成分为酸性火山岩,砂岩结构成熟度低,分选磨圆差。碎屑组分分析表明物源集中在火山弧物源区,地球化学特征为硅质含量高、LREE富集、HREE相对亏损、显示Eu负异常,均表明物源与酸性火山岩密切相关;日贡拉组砂岩的大地构造背景主要为大陆岛弧,砂岩碎屑来自上地壳长英质源区。重矿物组合以反映物源为中酸性岩浆岩成分的赤褐铁矿+磁铁矿、锆石、电气石、石榴子石为主,沉积环境为气候干旱、水体较浅的富氧环境。锆石形态特征指示物源距母岩区较近,重矿物的相关性分析也指示了物源与火山岩密切相关。研究区的日贡拉组砂岩与早白垩酸性火山岩微量元素及重矿物的对比表明,碎屑物质源区特点从岩石学特征、地球化学特征及重矿物组合特征上均表现出了亲缘关系,物源成分与火山作用紧密相关,很可能主要来自班公湖-怒江洋壳南向俯冲与雅鲁藏布江洋壳北向俯冲双重制约条件下产生于火山弧环境中的早白垩世火山岩。日贡拉组发现了砂岩型铜矿,火山岩提供了成矿物质来源,为寻找同类型的矿床开启思路。     

Lithofacies associations and structural evolution of the Archean Rio das Velhas greenstone belt,Quadrilátero Ferrífero,Brazil: A review of the setting of gold deposits

The Rio das Velhas greenstone belt is located in the Quadrilátero Ferrífero region, in the southern extremity of the São Francisco Craton, central-southern part of the State of Minas Gerais, SE Brazil. The metavolcano–sedimentary rocks of the Rio das Velhas Supergroup in this region are subdivided into the Nova Lima and Maquiné Groups. The former occurs at the base of the sequence, and contains the major Au deposits of the region. New geochronological data, along with a review of geochemical data for volcanic and sedimentary rocks, suggest at least two generations of greenstone belts, dated at 2900 and 2780 Ma. Seven lithofacies associations are identified, from bottom to top, encompassing (1) mafic–ultramafic volcanic; (2) volcano–chemical–sedimentary; (3) clastic–chemical–sedimentary, (4) volcaniclastic association with four lithofacies: monomictic and polymictic breccias, conglomerate–graywacke, graywacke–sandstone, graywacke–argillite; (5) resedimented association, including three sequences of graywacke–argillite, in the north and eastern, at greenschist facies and in the south, at amphibolite metamorphic facies; (6) coastal association with four lithofacies: sandstone with medium- to large-scale cross-bedding, sandstone with ripple marks, sandstone with herringbone cross-bedding, sandstone–siltstone; (7) non-marine association with the lithofacies: conglomerate–sandstone, coarse-grained sandstone, fine- to medium-grained sandstone. Four generations of structures are recognized: the first and second are Archean and compressional, driven from NNE to SSW; the third is extensional and attributed to the Paleoproterozoic Transamazonian Orogenic Cycle; and the fourth is compressional, driven from E to W, is related to the Neoproterozoic Brasiliano Orogenic Cycle. Gold deposits in the Rio das Velhas greenstone belt are structurally controlled and occur associated with hydrothermal alterations along Archean thrust shear zones of the second generation of structures.Sedimentation occurred during four episodes. Cycle 1 is interpreted to have occurred between 2800 and 2780 Ma, based on the ages of the mafic and felsic volcanism, and comprises predominantly chemical sedimentary rocks intercalated with mafic–ultramafic volcanic flows. It includes the volcano–chemical–sedimentary lithofacies association and part of the mafic–ultramafic volcanic association. The cycle is related to the initial extensional stage of the greenstone belt formation, with the deposition of sediments contemporaneous with volcanic flows that formed the submarine mafic plains. Cycle 2 encompasses the clastic–chemical–sedimentary association and distal turbidites of the resedimented association, in the eastern sector of the Quadrilátero Ferrífero. It was deposited in the initial stages of the felsic volcanism. Cycle 2 includes the coastal and resedimented associations in the southern sector, in advanced stages of subduction. In this southern sedimentary cycle it is also possible to recognize a stable shelf environment. Following the felsic volcanism, Cycle 3 comprises sedimentary rocks of the volcaniclastic and resedimented lithofacies associations, largely in the northern sector of the area. The characteristics of both associations indicate a submarine fan environment transitional to non-marine successions related to felsic volcanic edifices and related to the formation of island arcs. Cycle 4 is made up of clastic sedimentary rocks belonging to the non-marine lithofacies association. They are interpreted as braided plain and alluvial fan deposits in a retroarc foreland basin with the supply of debris from the previous cycles.     

西昆仑赛力亚克混杂堆积中砂岩块体的主要特点

西昆仑赛力亚克混杂堆积由形态、颜色和大小各异的沉积岩块体以及黑色泥质粉砂岩夹灰紫绿色钙质页岩、泥灰岩和层凝灰岩的基质组成。露头上块体和基质界线一般清楚，岩块主要是岩屑石英砂岩、凝灰质杂砂岩、长石质杂砂岩、石英质杂砂岩和碳酸盐岩类等。它们分布受麻礼－康西瓦－木孜塔格构造带的控制，是在残留海沟带，通过碎屑流、重力流的作用形成一套特殊的沉积混杂体。     

保山地块西缘早古生代增生造山作用

在保山地块西缘泸水-潞西构造带内, 出露一套构造混杂岩.主体为强变形的震旦系-古生界蒲满哨群、公养河群浅变质碎屑岩夹碳酸盐岩及火山岩等复理石浊积岩系等构成, 另有硅质岩、杂砂岩、灰岩、砾岩、玄武岩及花岗岩等弱变形的构造块体.岩石时代从震旦纪至古生代, 跨度大, 高度混杂, 并有从东向西变新的逐势, 表现为后退式增生.构造样式早期为同斜倒转冲断作用的叠瓦构造, 后期表现为近N-S向剪切.玄武安山岩、流纹岩类具弧火山岩特征, 而玄武岩类则为板内火山岩, 2种火山岩分别对应岛弧与弧后拉张洋盆产物.寒武纪、奥陶纪侵位的花岗岩也分为东西2个带, 西晚东早, 代表了保山陆块西缘岩浆弧的一部分.这样就记录了洋壳俯冲消亡、增生楔形成过程的沉积、火山-岩浆、变质和构造变形的地质事件群, 也记录了保山地块西缘早古生代增生造山形成过程的地质事件, 并证明了泸水-潞西构造带在震旦纪-古生代存在一洋盆.      

Cretaceous accretionary–collision complexes in central Indonesia

The geology of Cretaceous accretionary–collision complexes in central Indonesia is reviewed in this paper. The author and his colleagues have investigated the Cretaceous accretionary–collision complexes by means of radiolarian biostratigraphy and metamorphic petrology, as well as by geological mapping. The results of their work has revealed aspects of the tectonic development of the Sundaland margin in Cretaceous time. The Cretaceous accretionary–collision complexes are composed of various tectonic units formed by accretionary or collision processes, forearc sedimentation, arc volcanism and back arc spreading. The tectonic units consist of chert, limestone, basalt, siliceous shale, sandstone, shale, volcanic breccia, conglomerate, high P/T and ultra high P metamorphic rocks and ultramafic rocks (dismembered ophiolite). All these components were accreted along the Cretaceous convergent margin of the Sundaland Craton. In the Cretaceous, the southeastern margin of Sundaland was surrounded by a marginal sea. An immature volcanic arc was developed peripherally to this marginal sea. An oceanic plate was being subducted beneath the volcanic arc from the south. The oceanic plate carried microcontinents which were detached fragments of Gondwanaland. Oceanic plate subduction caused arc volcanism and formed an accretionary wedge. The accretionary wedge included fragments of oceanic crust such as chert, siliceous shale, limestone and pillow basalt. A Jurassic shallow marine allochthonous formation was emplaced by the collision of continental blocks. This collision also exhumed very high and ultra-high pressure metamorphic rocks from the deeper part of the pre-existing accretionary wedge. Cretaceous tectonic units were rearranged by thrusting and lateral faulting in the Cenozoic era when successive collision of continental blocks and rotation of continental blocks occurred in the Indonesian region.     

新疆卡拉麦里上-中泥盆统间角度不整合和346.8 Ma后碰撞火山岩的意义

在东准噶尔卡拉麦里地区的五彩湾一带出露一套具磨拉石特征的火山沉积建造, 下部为具磨拉石特征的砾岩、砂岩, 上部为一套中基性的火山熔岩夹中酸性的火山凝灰岩.1:20万卡拉麦里山幅将其归入下石炭统松喀尔苏组.通过1:5万地质调查研究发现, 该火山沉积建造底部以一套粗砾岩高角度不整合于下-中泥盆统卡拉麦里组之上, 含晚泥盆世植物化石Prelepidodendron sp.(先鳞木), 中上部火山岩LA-ICP-MS锆石U-Pb年龄为346.8±3.3 Ma, 且被年龄为341.1±4.0 Ma~340.9±5.1 Ma后碰撞花岗岩侵入, 表明其形成时代为晚泥盆世-早石炭世, 时代上对应于北准噶尔地层分区的上泥盆统克安库都克组.该套地层中上部的火山岩的岩石组合为玄武岩、玄武安山岩、夹少量的流纹质凝灰岩, 岩石化学特征上属钙碱性-高钾钙碱性系列, (La/Yb)_N=2.97~6.66, Nb、Ta亏损, 部分样品Zr、Ti弱显亏损, Nb/U、Ce/Pb比值分别为7.43~20.88、3.17~12.45.地球化学特征表明其兼具板内火山岩和弧火山岩的某些特点, 形成于后碰撞伸展环境, 是卡拉麦里洋盆于晚泥盆世之前闭合后后碰撞岩浆活动的产物.这一研究成果对广为关注的卡拉麦里洋盆的闭合时间进行了很好的限定.