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1.
The Qilian Orogen of north western China records mid-Paleozoic collisional suturing of arc and continental blocks onto the south western margin of the North China craton. Silurian strata from the retroarc foreland basin mark the transition from ocean closure and northward subduction to the initiation of collision suturing. Detrital zircons were analysed from the western and eastern parts of the basin and show a spectrum of ages from Archean to Paleozoic with major age concentrations at around 2.5 Ga, 1.6 Ga, 1.2 Ga, 0.98 Ga, 0.7 Ga and 0.45 Ga. Archean age grains are derived from the North China craton, whereas the Central Qilian Bloc, which lies to the south provides the likely source for the bulk of the Proterozoic detritus. Paleozoic grains are restricted to Early Silurian samples from the western part of the basin and are considered to have been derived from the magmatic arc related to ocean closure and ultimate collision of the Central Qilian Belt with the North China craton. 相似文献
2.
早期碰撞造山过程与板块构造:前寒武纪地质研究的机遇和挑战 总被引:3,自引:0,他引:3
普遍认为修正后的板块构造模式仍适用于新太古代地质研究,但是早期板块构造过程与后期有明显差异,包括陆块规模、造山带类型、碰撞造山过程等。典型碰撞造山带在地史上的初次形成具有划时代的构造演化意义,涉及典型板块构造初始发生过程、最早超级大陆拼合、威尔逊旋回及板块碰撞造山过程等方面。华北中部保留一条近南北向的碰撞造山带(2 600~2 500 Ma BP),保留特征的巨型复式褶皱、不同层次推覆构造、蛇绿岩混杂带等。围绕华北中部造山带及其25亿年重大构造热事件的研究,对认识华北早期构造演化及其超大陆再造具有重要意义,也是早期板块构造研究的关键突破口之一,开展其不同地壳层次构造变形及其前陆盆地的研究,将深化早期板块边界及其造山过程的科学认识。 相似文献
3.
东秦岭-大别山及邻区盆-山系统演化与动力学 总被引:9,自引:0,他引:9
东秦岭-大别造山带受不同块体间的拼合碰撞及其之后的陆内变形控制,在造山带边缘和内部形成了不同的盆山系统。造山带北缘响应北秦岭与华北板块的弧陆碰撞及其之后陆内变形作用,形成了后陆逆冲与弧后前陆盆地系统。造山带南缘三叠纪至白垩纪随着扬子板块与秦岭-大别微板块沿勉略缝合带自东向西的斜向俯冲和之后的陆内旋转挤压,在扬子北缘形成了前陆逆冲与周缘前陆盆地系统。自晚侏罗世末至白垩纪造山带挤压与伸展并存,伸展自核部向边缘发展,形成造山带伸展塌陷与近东西向裂谷盆地系统。大致在中始新世之后,受中国东部环太平洋构造带东西向伸展作用和深部构造作用控制,横跨造山带形成近南北向的裂谷盆地。 相似文献
4.
The Paleoproterozoic North Hebei Orogen: North China craton's collisional suture with the Columbia supercontinent 总被引:36,自引:4,他引:32
Understanding the geologic history and position of the North China craton in the Paleoproterozoic Columbia supercontinent has proven elusive. Paleoproterozoic orogenic episodes (2.00–1.85 Ga) are temporally associated with ultimate stabilization of the North China craton (NCC), followed by the development of extensive craton-wide rift systems at 1.85–1.80 Ga. The age difference between the sedimentary cover and the metamorphic basement is up to 500–700 Ma, suggesting that uplift and doming of cratonic basement occurred in the latest Paleoproterozoic. Mafic dike swarms (1.80–1.77 Ga) and anorogenic magmatism (1.80–1.70 Ga) record the extensional breakup and dispersal of the North China craton during this stage. The late Paleoproterozoic tectonic framework and geological events documented provide important constraints for reconstruction of the NCC within the Late Paleoproterozoic supercontinent of Columbia.An east-west striking thousand kilometer long belt of khondalites (granulite facies metapelites) stretches along the northern margin of the North China craton, on the cratonward side of the Northern Hebei orogenic belt. This granulite belt includes Mg–Al (sapphirine bearing) granulites that reached ultrahigh-temperature “peak” metamorphic conditions of 1000 °C at 10 kbars at 1927 ± 11 Ma. Following peak ultrahigh-temperature conditions, the rocks underwent initial isobaric cooling and subsequent isothermal decompression, and these trajectories are interpreted to be part of an overall anti-clockwise P-T evolution indicating that the northern margin of the craton experienced continental collision at 1.93–1.92 Ga. The position of the khondalite belt south of the Northern Hebei orogenic belt makes it analogous to Tibet, a continental collision-related plateau characterized by double crustal thicknesses and granulite facies metamorphism at depth. We suggest that the tectonic evolution of the NCC during this period was closely related to the assembly and break-up of the Columbia supercontinent, and that the NCC was adjacent to the Baltic and Amazonian cratons in the period 2.00–1.70 Ga. Craton-wide extension occurred within 100–150 Ma of collision along the northern margin of the craton at 1.93–1.92 Ga. It is concluded that mantle upwellings are chiefly responsible for the breakup of the NCC from the Paleoproterozoic supercontinent. 相似文献
5.
四川松潘—甘孜盆地砂岩的物质来源:来自锆石U Pb(SHRIMP)年龄证据 总被引:9,自引:0,他引:9
松潘—甘孜复理石带(位于中国中部)呈巨大的三角形区域,面积2.0×105km2以上,其周围分别是华南板块、华北板块以及青藏高原大陆地块。从该带中部采集了六个砂岩样品,用U Pb法对其中的锆石逐个进行分析。碎屑锆石的有较大的年龄变化范围,其年龄主要集中在元古代,并且含少量的晚太古代(25~26亿年)物质,其它年龄反映从四堡期到三叠纪的印支期岩浆喷发事件。低U含量的锆石不协和性与铅丢失型式表明可能是由于后来岩浆喷发事件所致。加里东期锆石年龄峰值表明碎屑沉积物的源区可能来自北秦岭,其它的主要为扬子克拉通北缘、南秦岭。 相似文献
6.
中元古代超大陆Rodinia 再造研究最重要的问题之一就是围绕全球格林威尔期(1.0Ga)造山带的构造演化对比,详细的构造分析表明,我国境内至少存在两条格林威尔期造山带(北秦岭造山带及江南造山带),它们以活动陆缘增生型造山带为主,涉及板块俯冲、岛弧-弧后盆地的发育,以及微陆块的碰撞作用。这些造山带发育的时代主要集中于1.0-0.9Ga,它们在时代上与北美、欧洲格林威尔期造山带具有很好的可比性,成为制约我国主要陆块(华北、扬子)在超大陆中拼合方式最主要的证据之一。 相似文献
7.
《Gondwana Research》2013,24(4):1342-1364
Based mainly on field geological observation and geochronologic data, six tectonic units have been recognized in western Inner Mongolia (China), including, from south to north: North China Craton (NCC), Southern Orogenic Belt (SOB), Hunshandake Block (HB), Northern Orogenic Belt (NOB), South Mongolia microcontinent (SMM), and Southern margin of Ergun Block (SME), suggesting that the tectonic framework of the CAOB in western Inner Mongolia is characterized by an accretion of different blocks and orogenic belts. The SOB includes, from north to south, fold belt, mélange, arc-pluton belt, and retroarc foreland basin, representing a southern subduction–collision system between the NCC and HB blocks during 500–440 Ma. The NOB consists also of four units: arc-pluton belt, mélange, foreland molasse basin, and fold belt, from north to south, representing a northern subduction–collision system between the HB and SMM blocks during 500–380 Ma. From the early Paleozoic, the Paleo-Asian oceanic domains subducted to the north and the south, resulting in the forming of the SOB and the NOB in 410 Ma and 380 Ma, respectively. This convergent orogenic system, therefore, constrained the consumption process of the Paleo-Asian Ocean in western Inner Mongolia. A double subduction–collision accretionary process is the dominant geodynamic feature for the eastern part of the CAOB during the early to middle Paleozoic. 相似文献
8.
南非境内矿产资源种类繁多、储量巨大,其内部的构造单元包括一个太古宙克拉通与一系列元古宙-古生代造山带,以及一个代表弧后前陆沉积系统的卡鲁盆地(狭义)。文章结合区域构造演化与成矿关系,将南非划分为6个Ⅲ级成矿区带:太古宙卡普瓦尔克拉通金-铀、铁-铜-铂族元素、金刚石成矿区,古元古代林波波金-金刚石成矿,古元古代海斯铁-锰成矿带,中元古代那马奎铜-铅-锌多金属成矿,古生代开普褶皱带钨-锡-铜-钼多金属成矿带,古生代-中新生代卡鲁盆地铀-金刚石-砂金成矿区。 相似文献
9.
北祁连造山带晚奥陶世-泥盆纪构造演化: 碎屑锆石年代学证据 总被引:3,自引:0,他引:3
北祁连造山带晚奥陶世-泥盆纪处于同造山的构造背景.上奥陶统-泥盆系沿造山带不对称分布.上奥陶统-泥盆系碎屑锆石年代学特征显示, 造山带东段武威一带上奥陶统底部沉积物主要来自北祁连岛弧, 南部中祁连地块和北部华北板块的沉积物在上奥陶统上部才出现, 根据同沉积锆石年龄将中祁连地块和华北板块在东段初始碰撞的时间限定在470~450 Ma之间; 中祁连地块和华北板块的物质在造山带西段肃南一带被保存在下志留统, 地层中也有大量来自早古生代北祁连岛弧和同碰撞花岗岩的物质, 暗示造山带西段的碰撞时间在早志留世.而造山带东段下志留统中却仅有来自中祁连地块和华北板块的物质, 缺乏代表北祁连岛弧的早古生代碎屑锆石年龄, 对比上奥陶统-下志留统岩相分布和碎屑锆石年代学特征, 北祁连造山带的碰撞具有"东早西晚"的"斜向碰撞、不规则边缘碰撞"的特征, 而这种碰撞方式导致中祁连地块在造山带东段仰冲到北祁连岛弧之上, 阻止北祁连岛弧为盆地提供沉积物; 泥盆纪早期, 北祁连岛弧年龄在东段下、中泥盆统中重新出现, 结合志留系和泥盆系在造山带东、西两段的分布和变形特征推断, 泥盆纪早期北祁连造山带具有"东强西弱"的不均一隆升特征, 这种差异隆升特征是由"东早西晚"的"斜向碰撞、不规则边缘碰撞"引起的, 它导致了北祁连岛弧在造山带东段被重新剥露出地表, 同时来自早期中、上志留统以及同碰撞花岗岩的物质也被汇入盆地.河西走廊盆地性质经历了弧后盆地-弧后残留洋盆-前陆盆地的转换过程. 相似文献
10.
鄂尔多斯西南缘前陆盆地沉积物物源分析及其构造意义 总被引:32,自引:0,他引:32
前陆盆地充填沉积物中岩屑的分散形式和砂岩成分研究对确定物源区的逆冲事件、构造背景和与沉积物对应的物源层十分有效。通过对鄂尔多斯西南缘安口地区上三叠统沉积剖面系统采样测定发现,沉积物物源为一套变质碎屑岩和变质火山岩,为东祁连褶皱逆冲带中的陈家河组(O3ch)和葫芦河组(Z-O2hl)。而西南缘千阳县上侏罗统砾岩物源为陇山群(Pt2ln)。上三叠统地层的物源分散形式为混合型,而上三叠统和上侏罗统两套地层统一的分散型式为倒序型,它是两期逆冲活动的沉积响应。根据鄂尔多斯西南缘安口地区上三叠统沉积物的QmFLt端元成分作砂岩三角投影图,确定晚三叠世鄂尔多斯西南缘盆地性质为发育于碰撞造山带之前陆的前陆盆地。其物源为再旋回活动的褶皱逆冲断块 相似文献