塔吉克斯坦托赫塔梅什一带铁铜多金属矿化体的发现及其成因分析

近年来在塔吉克斯坦南帕米尔托赫塔梅什地区发现数条铁铜多金属矿化体,对该矿化体进行野外地质调查、岩相学研究、遥感解译等工作,结合矿石的化学分析、X 衍射分析、光谱半定量分析、电子探针分析结果,综合研究认为, 铁铜多金属矿化体的形成与海相火山作用有关,该地区无论是寻找铁矿还是铜矿,从近铜远铁的成矿模式,都具有较大的找矿潜力。同时,该地区此类矿产的发现对指导中国境内西昆仑的找矿勘查提供思路。     

帕米尔地区深震震相特征及震源定位的初步研究

根据中国、塔吉克双方地震资料，研究帕米尔地区深震震相特征及震源定位。结果表明：区内深震震相有明显的区域特征，由新疆境内的数台资料，可以识别深震震相；用直达波来模拟深震源地震Ｐ、Ｓ波的传播是可行的，试算震例说明，在一定的震中距范围内（△＜８°），精度完全符合使用要求；帕米尔地区速度模型，经过反复分析测算，及几十次震例计算验证，可以推广使用。     

帕米尔中部North Kyzkurgan冰川跃动变化遥感监测

跃动冰川作为一种特殊类型的冰川,蕴含着巨大的灾害风险,对其开展监测研究具有重要意义。本研究基于1973年以来的Landsat影像、ASTER立体像对和ITS_LIVE数据产品,监测分析了帕米尔中部North Kyzkurgan冰川在跃动前、跃动中、跃动后的面积、高程、流速变化,揭示了该冰川完整的跃动发生过程。结果表明：North Kyzkurgan冰川是一条典型的跃动冰川,在1973—2011年处于恢复阶;2011—2016年处于跃动阶;2016年之后重新进入恢复阶。North Kyzkurgan冰川所在地区气候寒冷,降雪量丰富,同时该冰川积累区面积比率超过0.8,冰川作用正差近1 000 m,因此冰川补给物质充足。在积蓄区物质积累、不断增厚的情况下,冰川底部达到压力熔点,融水不断增多,在融水的润滑和顶托作用下,最终导致冰川发生跃动。因此,North Kyzkurgan冰川跃动的发生主要与热力学因素有关。     

Evolution of the great river systems of southern Asia during the Cenozoic India–Asia collision: Rivers draining north from the Pamir syntaxis

During uplift of the Tibetan plateau and surrounding ranges, tectonic processes have interacted with climatic change and with local random effects (such as landslides) to determine the development of the major river systems of Asia. Rivers draining northward from the Pamir syntaxis have three distinctive patterns that are controlled by different tectonic and climatic regimes. West of the Pamir, the rivers have moderate but irregular gradients and drain northwards to disappear into arid depressions. Relatively steady uplift of the Hindu Kush in northern Afghanistan allowed rivers to cut across the rising ranges, modified by the shear along the Harirud fault zone, local faulting, and by increasing rain-shadow effects from the rising Makran. In the transition to the Pamir the rivers have steeper but more even gradients suggesting more even flow and downcutting during uplift, possibly related to larger glacial sources. In the central Pamir, only one antecedent river, the Pyandzh appears to have kept its northward course with compression and uplift of the indenter, and its course strangely corresponds with a major geophysical boundary (a distorted subducted slab) but not a geological boundary: the other rivers are subsequent rivers developed along deformation fronts during development and northward displacements of the Pamir structural units. The above areas have sources north of the Cretaceous Karakorum–South Pamir Andean margin. On the eastern flank of the Pamir, in the Kunlun and northern Tibetan plateau, the rivers rise similarly north of the Cretaceous Andean margin of southern Tibet, but then flow with low gradients across the plateau, before cutting and plunging steeply down across the Kunlun to disappear into the arid Tarim. These steep profiles are the result of late Neogene uplift of the northern Tibetan plateau and Kunlun possibly modified by glacial diversion and river capture. The drainage history of the Pamir indenter can be reconstructed by restoring the gross movements of the plates and the tectonic displacements, uplift, and erosion of individual tectonic units. Most important changes in drainage took place in the last 10 million years, late Miocene to Quaternary times, as the Pamir syntaxis developed.     

东帕米尔高原喀拉库勒湖的成因及其年代

喀拉库勒湖位于东帕米尔高原的康西瓦河流域.研究区的地质构造资料显示,断层活动形成的慕士塔格-公格尔山之间的断层谷是喀拉库勒湖形成的基础.对本区的地貌考察得知,源自慕士塔格峰东坡和公格尔山西坡的古冰流曾数次占据整个河源区,形成规模较大的山麓冰川.现存的喀拉库勒湖为一冰碛堰塞湖,其形成时间与最后一次古冰流填充河源区,阻塞慕士塔格峰西北侧自西南向东北汇入康西瓦河的阔克萨依克河水流的时间相一致.应用OSL测年技术对采自喀拉库勒湖外围冰碛丘陵中的砂质透镜体进行定年,获其年代范围为(26.8±1.3)~(41.7±4.4)ka.结合本区已有的ESR年代学资料(37.8±3.6)~(48.2±4.6)ka、邻近区域的古气候记录以及我国西部第四纪冰川演化序列综合分析可以得出,喀拉库勒湖主要形成于末次冰期中冰阶,时间上可对应于MIS3中期.     

Characteristics and Formation Mechanism of Thrust Structures in the Eastern Margin of Pamir Salient: Insights from Analogue Modeling and DiscussionEI北大核心CSCD

Two models with different boundary conditions were carried out to simulate the structural evolution of the Kekeya-Hetian fold-and-thrust belt and Kashi-Yecheng strike-slip belt in the eastern margin of Pamir salient, respectively. The analogue modeling results show that: (1) Both of the Kekeya-Hetian fold-and-thrust belt and Kashi-Yecheng strike-slip belt in the eastern margin of Pamir salient were formed under compressive shearing. Strike-slip faults occurred within both of the belts, but the displacement of these strike-slip faults in the Kekeya-Hetian fold-and-thrust belt is less than that in the Kashi-Yecheng strike-slip belt; (2) The Kekeya-Hetian fold-and-thrust belt is mainly under the influence of compression stress with weaker shearing stress while the Kashi-Yecheng strike-slip belt is mainly under the influence of shearing stress with oblique compressive stress. The strike-slip faults are mainly located in the piedmont within these two belts. The effect of the strike-slip fault diminishes towards the front of the thrust belt (to the interior basin); (3) In the front of the boundary strike-slip faults (to the interior basin), the intersecting arc thrust faults occurred successively along the shortening direction. These structural features demonstrated that the structures evolved northwards in the eastern margin of Pamir salient; (4) The oblique compression does not necessarily result in high angle faults or vertical faults, whereas low-middle angle thrust faults with strike-slip displacement are also possible. Hence, more attention should be paid to such thrust faults during the structural analysis of seismic profiles in the eastern margin of Pamir salient (e.g. the structural belts in piedmont of western Tarim Basin). © 2017, Science Press. All right reserved.     

Stress field in the western Himalaya with special reference to the 8 October 2005 Muzaffarabad earthquake

The Muzaffarabad region in western Himalaya, the site of the devastating earthquake of 8 October 2005 of magnitude 7.6, occupies a unique tectonic position, encompassed by the Himalayan arc to the east and the complex thrust zones of Pamir and Hindukush in the north and northwest respectively. Further, the region is entangled in a peculiar overturned syntaxial bend of the Main Central Thrust (MCT), north of Main Boundary Thrust (MBT). A study of focal mechanisms and stress inversion in each of these regions indicates varied stress regimes demonstrating their distinct tectonic character. While shallow plane thrust faulting with low dip angles is generally witnessed along the Himalayan arc, a transition to steep fault plane dips up to 45° is seen in the Muzaffarabad region on the western side. It is inferred that the stress field in Muzaffarabad region is not a mere extension of that in the Himalayan arc but is controlled by the complex interplay of the surrounding diverse tectonic structural units comprising the Himalaya, Hindukush and Pamir, rather than merely the tectonic forces of India–Eurasia collision.     

西构造结—帕米尔及周边深部结构与构造探榷

帕米尔高原是五大山脉汇结之中心,被称为"西构造结".在此山高耸谷陡深是人迹罕至的无人区.应用稀少的地面重力和人工地震数据和卫星重力资料,以NNW和NEE向两条长达1620 km的十字交叉剖面,对帕米尔高原地区地壳深部结构与区域地质构造进行了研讨.帕米尔高原中心地区地壳厚度(莫霍界面深度)接近70 km,并在总体上呈向四周逐渐延展减薄(变浅)的总趋势,到帕米尔的周边地区减薄为50余km左右.这里是一个壳幔结构变异的构造强烈活动地域.     

Mesozoic–Cenozoic Tectonic Evolution and Uplift in Pamir: Application of Fission Track Thermochronology

The Pamir Plateau can be divided into three secondary tectonic units from north to south: the North, the Middle and the South Pamir Blocks. The North Pamir Block belonged to the southern margin of Tarim-Karakum, thermochronological study of the Pamir structural intersection indicates that accretion of the Middle Pamir Block to the Eurasian Continental Margin and its subduction and collision with the North Pamir Block occurred in the Middle–Late Jurassic. Due to the Neo-Tethys closure in the Early Cretaceous, the South Pamir Block began to collide with the accretion(the Middle Pamir Block) of the Eurasian Continental Margin. Affected by the collision and continuous convergence between the Indian Plate and the Eurasian Plate since the Cenozoic, Pamir is in a multi-stage differential uplift process. During 56.1–48.5 Ma, North Pamir took the lead in uplifting, that is, the first rapid uplift in the Pamir region began there. The continuous compression and contraction of the Indian and Eurasian plates during 22.0–15.1 Ma forced the Pamir tectonic syntaxis to begin its overall uplift, i.e. Pamir began to enter the second rapid uplift stage in the Early Oligocene, which lasted until the Middle Miocene. During 14.6–8.5 Ma, South Pamir was in a rapid uplift stage, while North Pamir was in a relatively stable state, showing asymmetry of tectonic deformation in the Pamir region in space. Since 6.5 Ma, Pamir began to rapidly uplift again.     

东帕米尔高原冰川运动特征分析

冰川运动控制着冰量输送变化,为冰川变化和冰川灾害研究提供重要信息.为了探讨东帕米尔高原冰川运动特征及其影响因素,基于ITS_LIVE和GoLIVE分析了不同规模、不同地形条件、表碛/非表碛区域的冰川运动速度状况.研究结果表明:(1)东帕米尔高原冰川平均运动速度为5.31 m·a-1,冰川运动速度与冰川规模相关,表现为大...