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11.
文中采用遥感资料,对阿尔泰山东缘的主要活动断裂———科布多(Hovd)断裂与哈尔乌苏湖(Har-Nuur)断裂进行研究,从地貌特征上对断裂进行详细分析,揭示其几何学和运动学特征。初步研究表明阿尔泰山东缘的活动断裂规模、滑动速率和强地震活动并不弱于其西南缘。其中科布多断裂走向NNW,右旋走滑,长约600km,中更新世(Q2p)以来最大水系右旋位错约9.0km,滑动速率可达3.8~12.3mm/a,平均滑动速率约7.8mm/a;哈尔乌苏湖断裂走向NNW,右旋走滑,长约480km,全新世以来活动性明显增强,第四纪洪积扇上发现有最新的断裂迹象。阿尔泰山东缘的新构造运动与强地震活动,除了与印度-欧亚板块碰撞作用有关外,可能还与局部地区的动力学过程有关 相似文献
12.
基于SRTM-DEM的阿尔泰山构造地貌特征分析 总被引:1,自引:0,他引:1
基于美国SRTM-DEM数据,利用彩色晕染、密度分割与GIS空间统计分析等技术,并结合地质资料,通过地形高程、地表坡度
及地形剖面等分析手段,对阿尔泰山的构造地貌特征进行初步分析。研究表明,阿尔泰山脉平均海拔约1 790 m,平均坡度约21°
,其高海拔与高坡度的现代地貌特征,主要与强烈的断裂构造活动有关; 山脉严格受到以北西向为主的断裂构造活动的影响与控
制,其发育的构造地貌单元基本上呈北西走向特征; 山脉阶梯状地貌特征明显,共发育5级剥夷面,不同级剥夷面所处的海拔不一
样,同级剥夷面具有东北侧高于西南侧,山脉东、中段高于西段的特点。 相似文献
13.
阿尔泰塔尔浪地区斜长角闪岩和辉长岩的形成时代、地球化学特征和构造意义 总被引:3,自引:0,他引:3
阿尔泰塔尔浪地区出露一些斜长角闪岩和辉长岩。其中,斜长角闪岩为基性岩浆岩变质的产物,SiO_2含量为45.42%~52.96%,具有较高的Al_2O_3(13.14%~17.92%)、Fe_2O_3~T(9.08%~16.88%)和TiO_2(0.82%~3.23%)含量。斜长角闪岩样品稀土元素曲线比较平坦,轻重稀土元素分馏不明显(La/Yb_N=1.53~1.79),无明显的Nb和Ta亏损。通过野外产状及地球化学特征分析,认为该斜长角闪岩形成于海山的构造环境。辉长岩SiO_2(46.96%~49.86%)含量稍低,TiO_2(0.38%~1.89%)变化较大,并富Al_2O_3(15.0%~20.81%)、CaO(10.13%~11.60%),具有中等至较高MgO含量(7.3%~8.3%)和相对较低的钾含量(K_2O=0.34%~1.03%),属亚碱性岩石系列(Na_2O>K_2O)。辉长岩呈现两种稀土元素组成特征。一种轻重稀土分馏不明显,配分曲线比较平坦(La/Yb_N=1.10~1.67),具有轻微的Eu正异常(δEu=1.03~1.10);另一种轻重稀土元素分馏较明显(La/Yb_N=5.97~6.39)并具有正的Eu异常(δEu=1.31~1.44),反映其形成过程中可能受到斜长石堆晶的影响。在微量元素蛛网图上,辉长岩具有明显的Ti、Nb和Ta负异常和Pb、Sr正异常,反映出明显的消减带岩浆特征。角闪石的~(40)Ar-~(39)Ar测年结果显示,辉长岩样品的坪年龄为266.9±6.1Ma,且年龄坪谱显示在其形成之后没有受到后期热事件的明显干扰,基本上反映了辉长岩的形成年龄。斜长角闪岩的~(40)Ar-~(39)Ar结果呈现出似马鞍型坪谱,其中最小的年龄坪(297.3±6.1Ma)可能反映了最近一期的变质事件,而且明显早于辉长岩的侵入。斜长角闪岩和辉长岩不同的形成时代和地球化学组成表明二者可能代表了两期不同的基性岩浆活动。斜长角闪岩所具有的板内和消减带的复合特征表明其原岩可能是洋壳在俯冲消减过程中增生的海山残片,而辉长岩所具有消减带特征显示在二叠纪时期阿尔秦地区仍存在受俯冲作用影响的地幔源区。阿尔泰二叠纪岩浆活动无论在岩浆属性还是规模上都与泥盆和石炭纪的岩浆活动存在巨大差异,表明这两个时期的构造背景存在较大不同,可能反映阿尔泰正处于某种构造转换机制的控制之下。 相似文献
14.
野外地质调查发现在阿尔泰南缘额尔齐斯构造带东段、额尔齐斯活动断裂与富蕴-锡泊渡断裂之间发育了一套未变形的酸性岩墙群。岩墙群侵位于海西期片麻岩化花岗岩和上石炭统深变质的额尔齐斯组岩层中,薄片鉴定和岩石地球化学分析确定为具有细晶结构的流纹斑岩。岩石的SiO_2含量为70.9%~75.38%,K_2O Na_2O含量为7.55%~8.99%;大部分样品Na_2O>K_2O,里特曼指数值为1.8~2.5之间,Al_2O_3=12.80%~14.53%,A/CNK=0.9~1.1,NK/A=0.7~0.9,具有准铝质—弱过铝质、低镁、高钾钠、低钙和锶、高(Fe)_(mol)/(Mg)_(mol)特点,具A型花岗岩类特点,属于亚碱性脉岩。岩石轻稀土富集,大离子亲石元素相对富集,具有明显的中等负铕异常,壳源特征明显。锆石U-Pb二次粒子微探针测年显示岩墙群形成于277~286Ma。推断岩墙是阿尔泰海西期造山运动结束后,在拉张构造环境下的地壳局部熔融产物。 相似文献
15.
Inna Safonova 《地学前缘(英文版)》2014,5(4):537-552
The paper reviews previous and recently obtained geological, stratigraphic and geochronological data on the Russian-Kazakh Altai orogen, which is located in the western Central Asian Orogenic Belt (CAOB), between the Kazakhstan and Siberian continental blocks. The Russian-Kazakh Altai is a typical Pacific-type orogen, which represents a collage of oceanic, accretionary, fore-arc, island-arc and continental margin terranes of different ages separated by strike-slip faults and thrusts. Evidence for this comes from key indicative rock associations, such as boninite- and turbidite (graywacke)-bearing volcanogenic-sedimentary units, accreted pelagic chert, oceanic islands and plateaus, MORB-OIB-protolith blueschists. The three major tectonic domains of the Russian-Kazakh Altai are: (1) Altai-Mongolian terrane (AMT); (2) subduction-accretionary (Rudny Altai, Gorny Altai) and collisional (Kalba-Narym) terranes; (3) Kurai, Charysh-Terekta, North-East, Irtysh and Char suture-shear zones (SSZ). The evolution of this orogen proceeded in five major stages: (i) late Neoproterozoic-early Paleozoic subduction-accretion in the Paleo-Asian Ocean; (ii) Ordovician-Silurian passive margin; (iii) Devonian-Carboniferous active margin and collision of AMT with the Siberian conti- nent; (iv) late Paleozoic closure of the PAO and coeval collisional magmatism; (v) Mesozoic post-collisional deformation and anarogenic magmatism, which created the modern structural collage of the Russian- Kazakh Altai orogen. The major still unsolved problem of Altai geology is origin of the Altai-Mongolian terrane (continental versus active margin), age of Altai basement, proportion of juvenile and recycled crust and origin of the middle Paleozoic units of the Gorny Altai and Rudny Altai terranes. 相似文献
16.
Catastrophic drainage of ice-dammed lakes in the Altai Mountains has been inferred from geomorphological evidence in the Katun Valley (Russia), and is presumed to have occurred during the Pleistocene. The sedimentary features have been difficult to date directly, due to the absence of organic carbon, and the improbability that luminescence signals in sand grains would be reset during transport. However, the development of rock-surface luminescence dating provides a new opportunity to date the features: clasts have a different transport history to sand grains, and their luminescence depth profiles can be inspected for evidence of bleaching before burial. Here we investigate two sites in the Altai Mountains, and use rock-surface luminescence burial dating to constrain the age of the megaflood deposits. In the Katun Valley, we sampled granite cobbles from a frozen sediment clast emplaced as a dropstone within a massive megaflood gravel terrace. Burial ages for the clasts range from 16.7 to 21.4 ka, with a mean age of 19.8 ± 1.5 ka. This represents the depositional age of the fluvial sediments that preceded the lake outburst flood, (and hence places a maximum age on the catastrophic flood). Clasts sampled from mega-ripples in the Kurai Basin are shown to have a mid-to-late Holocene burial age, which is not consistent with the possible origin of these features during a catastrophic drainage of a glacier-dammed lake. Instead, the burial age of the Kurai Basin sediments may reflect local-scale periglacial or seismic processes along the Kurai Fault Zone. 相似文献
17.
阿尔泰造山带位于西伯利亚板块与哈萨克斯坦-准噶尔板块之间,是中亚造山带重要组成部分。长期以来,阿尔泰何时结束造山一直存在争议,阻碍了对中亚造山带晚古生代构造演化的认识。中国阿尔泰造山带南缘发育早二叠世花岗岩,具有碱性或A型花岗岩特征,能够反映碰撞后伸展的构造环境。青河岩体位于阿尔泰造山带东南部,主要由二长花岗岩和少量闪长岩组成,具有研究阿尔泰造山带晚期构造演化的条件。本文以此为切入点,对青河岩体开展年代学和地球化学工作。新的测年数据表明似斑状二长花岗岩(283±3Ma)、中细粒二长花岗岩(280±2Ma)、糜棱岩化二长花岗岩(286±2Ma)和辉长闪长玢岩(269±1)均形成于早二叠世。岩体高硅(SiO_2=61. 98%~73. 35%),富碱(K_2O+Na_2O=5. 84%~8. 72%,碱度率AR=2. 12~3. 65),低钙(CaO=1. 29~3. 76%),里特曼指数σ=2. 38~2. 54,K_2O/Na_2O=0. 78~1. 06,属于高钾钙碱性岩石系列。微量元素显示Ba、Sr、P、Ti、Nb、Ta亏损,Eu明显负异常(δ_(Eu)=0. 46~0. 78),10000×Ga/Al=2. 85~2. 47,反映具有A型花岗岩特征,可作为阿尔泰碰撞造山作用结束的标志。另外,这些岩体ε_(Hf)(t)值介于+4. 04~+11. 78之间,二阶段模式年龄(t_(DM2))分别变化于880~694Ma、923~633Ma、875~555Ma、1030~635Ma,揭示其源区主要由新元古代幔源物质或新生地壳组成。结合区域上同时代、同构造位置富碱性(A型)花岗岩研究结果,认为青河中酸性岩体成因与地幔岩浆底侵早期下地壳有关,是新元古代玄武质物质再熔,并发生结晶分异的结果。因此,阿尔泰造山带于早二叠世(286~280Ma)已经结束了碰撞造山作用,处于伸展的构造背景。 相似文献
18.
19.
I. K. Kozakov T. I. Kirnozova Yu. V. Plotkina 《Stratigraphy and Geological Correlation》2009,17(1):36-42
In South Mongolia, the Hercynian structures of a linear collisional thrust-and-fold zone formed in the Carboniferous are bounded by the Caledonides of Central and North Mongolia on the north, being truncated on the south by the Indosinides of the Inner Mongolia. Tectonic sheets of the Caledonides-Hercynides junction zone confined to southern flank of the Mongolian-Gobi Altai are composed of high-gradient metamorphites of the South Altai metamorphic belt. The belt of these rocks traceable northwestward in China and eastern Kazakhstan delineates margin of the North Asian Caledonian paleocontinent. According to results of the previous geochronological study, the high- and low-gradient metamorphic rocks of the belt originated respectively 385 and 360–370 Ma ago. However, tectonic position of crystalline rock sequences, which have not been dated, remains unclear. Geochronological interval postulated for these rocks is very broad, ranging from the Early Precambrian to the Devonian. Dating results obtained in this work for detrital zircons from siliciclastic metasediments of the Bodonchin tectonic sheet of the belt show that their protoliths accumulated during the time span of 460–390 Ma (Late Ordovician-Early Devonian) on a passive continental margin. Transformation of the latter into active continental margin took place in the Early Devonian, when development of the Siberian subduction zone resulted in formation of the South Altai metamorphic belt at deep crustal levels of the Caledonian paleocontinent. 相似文献
20.