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1.
1966年邢台地震发生在华北平原中部的束麓断陷盆地及其邻近地区,为取得大震区地壳细结构,国家地震局系统的几个单位于1990年冬共同实施了一条穿过这一盆地的深地震反射剖面.测线通过7.2级主震震中位置(N37°32’,E115°03’),方位约N60°W,总长度约40km.它与元—济深地震测深剖面的震中区部分基本重合.深反射剖面采 相似文献
2.
《中国科学:地球科学》2015,(10)
对吕梁山地区中-新生代隆升时限及其演化的认识,是恢复鄂尔多斯盆地沉积东界的基础,也是探讨华北克拉通演化和破坏等科学问题的有机组成部分.本文以盆山耦合的研究思路为指导,通过较系统的裂变径迹热年代学采样分析,认为吕梁山地区显生宙的隆升活动主要发生在早白垩世晚期以来,可进一步分为缓慢抬升(120~65 Ma)、加速抬升(65~23 Ma)及强烈抬升(23 Ma以来)3个隆升演化阶段,新生代以来是其最主要的隆升时期.抬升作用在空间上具非均衡性,中、北部抬升早,南部晚.晚新生代以来吕梁山地区的快速隆升作用,与东部相邻断陷的沉降具有成因耦合联系.吕梁山地区晚中生代-新生代以来的隆升演化,可能主要与青藏高原挤压造山作用和太平洋板块俯冲的远程效应有关. 相似文献
3.
黄河中上游河段是横贯整个“柴达木 -祁连山活动地块”的贯流水系。通过对青海共和至宁夏石嘴山段长约 180 0km的黄河中上游阶地的系统考察、阶地剖面实测和年代测定 ,绘制了该河段的阶地纵剖面图。综合分析各段的阶地级数、高度、年代及变形特征得到以下认识 :该流域可划分为若干个次级活动地块 ,表现在不同地块之间的阶地抬升幅度和速率存在较大差别 ;活动地块内部在较大程度上具刚性特征 ,表现在块体内部阶地级数、高度和形成年代基本相当 ;阶地纵剖面反映的本区活动地块自 1.6MaB .P .以来的抬升量大于 3.6~ 1.6MaB .P .的抬升量 ;柴达木 -祁连山活动地块距今 1万年以来和 15~ 2 0万年间存在 2次强烈的构造抬升运动 相似文献
4.
冀北滦平侏罗-白垩系界线层序地层学研究 总被引:10,自引:0,他引:10
据沉积旋回和相序分析, 将冀北滦平张家沟剖面陆相侏罗-白垩系界线系统划分为5个层序、13个亚层序和139个副层序. 应用亚层序与副层序的稳定延续时限标定地层单位界线年龄值, 层序I (大北沟组)的底界为142.90 Ma, 层序Ⅱ的底界为141.16 Ma, 层序Ⅲ(大店子组)的底界为140.00 Ma, 层序Ⅳ(张家沟组)的底界为138.24 Ma, 层序Ⅴ(张家沟组)的顶界为135.34 Ma. 在层序界面和标志层追索及化石带等时对比基础上, 建立滦平盆地大北沟组~张家沟组层序地层格架. 据层序与层序界面成因分析和分布特征, 论述了构造阶段和盆地演化. 5个层序代表盆地发育的5个断陷-上升旋回, 6个层序界面的形成都显示构造活动影响. 盆地演化宏观上分为三大阶段, 每个阶段包括强烈抬升→剧烈断陷(伴随火山喷发)→逐渐抬升的构造旋回, 证明盆地断陷对应于沉积范围窄小、而抬升对应于范围扩展的演化规律. 相似文献
5.
吉隆盆地周缘构造变形特征及藏南拆离系启动年龄 总被引:6,自引:0,他引:6
藏南吉隆盆地位于喜马拉雅造山带内部,是藏南拆离系(STDS)和南北向裂谷交汇地区.该区自南而北可划分为5个构造-岩石单元:(1)高喜马拉雅岩系;(2)STDS大型剪切带;(3)特提斯喜马拉雅岩系;(4)晚新生带盆地,如吉隆、沃马盆地等;(5)马拉山穹隆构造期次可以划分为4期:(a)特提斯喜马拉雅和高喜马拉雅中均有残留的早期向南的逆冲构造;(b)STDS自南向北的伸展滑脱,与该运动相关的正断层形成新生代盆地的早期控制构造,盆地间断块掀斜方式指示北向滑脱运动;(c)东西向伸展作用形成南北向正断层,控制盆地东部边界;(d)晚期垮塌作用.来自STDS同构造花岗岩SHRIMPU-Pb年龄显示STDS主期活动时代约为26Ma,而其启动年龄可能早于36Ma. 相似文献
6.
《中国科学:地球科学》2017,(1)
青藏高原地表抬升历史是新生代以来众多地质事件和气候环境事件的边界条件.高原古高度变化历史将地球深部动力学、地表过程和气候变化等不同圈层的相互作用有机地联系在一起.各种古高度计的发展和在青藏高原的广泛应用推动了对高原隆升历史的进一步认识:早始新世时青藏高原主体由南部的冈底斯山(~4500m)和北部的羌塘中央山脉(~5000m)及夹于其间的低海拔盆地(~2500m)组成,而南部的喜马拉雅山仍处于接近海平面的位置,北部的可可西里盆地海拔高度也不超过1500m.具有"世界屋脊"之称的青藏高原直到中新世以后才基本形成.尽管如此,青藏高原各块体的隆升历史仍然不清,进而制约对整个青藏高原抬升历史的重建.只有尽可能运用不同的古高度计对同一地区进行研究,获得更多的不同地区精确的古高度历史,才能从整体上认识青藏高原的抬升和扩展的形式和过程. 相似文献
7.
在SinoProbe-01项目的资助下,完成了一条跨越鄂尔多斯地块北部、河套断陷盆地和阴山造山带的大地电磁剖面,剖面长约440 km,共包括24个宽频测点和4个宽频一长周期联合测点.采用NLCG算法对TE和TM模式数据进行了二维反演,获得了该剖面的二维电性结构模型.结果表明:鄂尔多斯地块北部由浅至深电性结构比较简单,成层性较好,大体可分为低阻沉积盖层-高阻上地壳-低阻下地壳和上地幔顶部三层;河套断陷盆地和阴山造山带电性结构相对复杂,电阻率高低相间.鄂尔多斯地块北缘、河套断陷盆地以及阴山造山带区域的壳幔高导体可能与硫化物和部分熔融作用有关,而鄂尔多斯地块内部大规模的壳幔高导层可能是由高导矿物引起的.河套断陷盆地的沉降、阴山造山带的地势抬升和鄂尔多斯地块北缘东胜一杭锦旗一带的的隆起之间有着紧密的关系,它们的形成可能与区域伸展构造环境条件下的软流圈物质上涌有关. 相似文献
8.
祁连山北缘老君庙背斜晚新生代磁性地层与高原北部隆升 总被引:36,自引:2,他引:36
河西走廊新生代沉积敏感地记录了青藏高原北部的构造隆升过程. 酒泉盆地玉门老君庙剖面高分辨率磁性地层研究表明, 疏勒河组胳塘沟段和牛胳套段的年龄分别为>13~8.3 Ma和8.3~<4.9 Ma, 玉门砾岩、酒泉砾石层和戈壁砾石层的年龄分别为3.66~0.93, 0.84~0.14和0.14~0 Ma. 岩性和岩相变化表明祁连山自约8 Ma起, 6.6 Ma略有加速, 由较低的高度开始逐步隆起, 盆地沉积从细粒的湖相砂岩-泥岩逐步转变成粗粒的洪积扇沉积, 至约3.66 Ma后, 祁连山开始急剧地整体快速隆升, 并经约<2.94~2.58, <1.8~1.23, 0.93~0.84和0.14 Ma多次阶段性快速隆升, 祁连山最终被抬升到今天的高度. 相似文献
9.
鄂尔多斯盆地东南缘处于渭北隆起、晋西挠褶带和东秦岭造山带的转折地带,构造位置独特,演化历史复杂.本文选取东缘韩城地区和南缘东秦岭洛南地区上三叠统延长组为研究对象,采集6件砂岩样品进行锆石、磷灰石裂变径迹分析,对关键构造-热事件提供热年代学约束,恢复盆地东南缘不同构造带的热演化史,深化对盆地东南部油气资源赋存条件的认识,以期实现油气勘探的新突破.研究表明韩城和洛南地区的抬升冷却史存在明显差异.磷灰石裂变径迹年龄表现为从南到北减小的趋势.东缘韩城剖面磷灰石裂变径迹记录51.6~66.3 Ma、33 Ma两次抬升冷却的峰值年龄.南缘洛南剖面锆石裂变径迹年龄和磷灰石裂变径迹年龄分别记录89~106 Ma和59~66 Ma的冷却抬升年龄.洛南地区抬升冷却时间较早,剥蚀速率(106m/Ma)大于韩城地区(68m/Ma),且持续时间长.磷灰石裂变径迹(Apatite Fission Track,AFT)热史模拟显示,晚中生代,受燕山运动的影响,东秦岭地区发生强烈的构造岩浆事件,洛南地区热演化程度明显高于韩城地区.洛南剖面的热演化主要受岩浆活动的控制,韩城剖面为埋藏增温型.鄂尔多斯盆地东南缘的裂变径迹年龄格局基本受控于白垩纪以来的抬升冷却事件. 相似文献
10.
跨呼和浩特-包头盆地(以下简称"呼包盆地")完成的91.8km长的深地震反射剖面,揭示了呼包盆地的岩石圈精细结构和断裂的深、浅构造特征.结果表明,本区地壳和岩石圈具有清晰的层状反射结构特征,其中,地壳厚度约45~48km,岩石圈厚度约82~87km.莫霍面在大青山之下出现约3.5km的抬升,暗示大青山的隆升不是因为地壳物质增厚所致,即大青山可能不存在"山根".呼包盆地为南浅、北深的"箕状"断陷盆地,盆地沉积层最厚处位于大青山山前,其厚度约为7~8km.鄂尔多斯北缘断裂和大青山山前断裂作为呼包盆地的南、北边界断裂,在剖面上均表现为由3~4条断裂组成的"Y"字形断裂构造,它们对呼包盆地的形成、地层沉积、基底变形和地震活动都有重要的控制作用.剖面揭示的岩石圈深断裂位于大青山山前断裂的下方,该断裂向上进入上地壳,向下切割中-下地壳、莫霍面,进入上地幔.深断裂的存在为深部热物质的上涌与能量强烈交换提供了通道,而上涌的软流层物质与岩石圈地幔发生交代和侵蚀作用导致岩石圈减薄. 相似文献
11.
Structure and deformation around the Gyirong basin,north Himalaya,and onset of the south Tibetan detachment system 总被引:4,自引:0,他引:4
Gyirong basin and its adjacent area are located at a special position in the Himalayan orogen, where the south Tibetan detachment
system (STDS) and N-S trending rift converged. The north Himalayan orogen here can be divided into five petrologic-tectonic
units successively from south to north: 1) the Greater Himalayan crystalline complex (GHC); 2) the STDS shear zone; 3) the
Tethyan Himalayan sedimentary sequence (THS); 4) the late Cenozoic sedimentary basins, such as Gyirong and Oma basins; and
5) the Malashan gneiss dome. Structural studies show that this area experienced four stages of deformation: 1) the earlier
south-directed thrusting, preserved both in the GHC and THS; 2) top-down-to-north slip along the STDS, normal faults related
to this slip formed the early controlling structures of the Cenozoic basins, and the tilted pattern of the blocks between
the basins indicated a north-directed slip; 3) east-west extension, the resultant N-S trending normal fault formed the eastern
boundary of the basins; and 4) late gravitational collapse. Zircon SHRIMP U-Pb dating on the syn-deformational (leuco-) granite
along the STDS indicates that the major activity of the STDS occurred at ca. 26 Ma, but its onset may have begun as early
as ca. 36 Ma.
Supported by National Natural Science Foundation of China (Grant Nos. 40821002, 40572115) 相似文献
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13.
Reconstruction of uplift history of the Tibetan Plateau is crucial for understanding its environmental impacts. The Oiyug Basin in southern Tibet contains multiple periods of sedimentary sequences and volcanic rocks that span much of the Cenozoic and has great potential for further studying this issue. However, these strata were poorly dated. This paper presents a chronological study of the 145 m thick and horizontally-distributed lacustrine sequence using paleomagnetic method as well as a K-Ar dating of the underlying volcanic rocks. Based on these dating results, a chronostratigraphic framework and the basin-developmental history have been established for the past 15 Ma, during which three tectonic stages are identified. The period of 15-8.1 Ma is characterized by intense volcanic activities involving at least three major eruptions. Subsequently, the basin came into a tectonically quiescent period and a lacustrine sedimentary sequence was developed. Around 2.5 Ma, an N-S fault occurred across the southern margin of the basin, leading to the disappearance of the lake environment and the development of the Oiyug River. The Gyirong basin on northern slope of the Himalayas shows a similar basin developmental history and thus there is a good agreement in tectonic activities between the Himalayan and Gangdise orogenic belts. Therefore, the tectonic evolution stages experienced by the Oiyug Basin during the past 15 Ma could have a regional significance for southern Tibet. The chronological data obtained from this study may provide some constraints for further studies with regard to the tectonic processes and environmental changes in southern Tibetan Plateau. 相似文献
14.
修改了England和Mckenzie的黏性薄层流变模型中控制大陆形变的连续性方程,将剥蚀作用对高原隆升演化的影响直接引入该方程,并考虑下伏地幔小尺度对流对增厚岩石层的搬离作用对高原隆升演化后期的影响,用有限差分法直接模拟青藏高原隆升过程. 数值模拟结果所显示的高原隆升演化过程与实际观测资料吻合较好,揭示了高原隆升演化过程的非平稳和多阶段的特性;同时还表明上地幔小尺度对流对岩石层底部的搬离作用可能是最近8Ma以来高原快速隆升的主导机制. 相似文献
15.
A 2.8 Ma record of environmental evolution and tectonic events inferred from the Cuoe core in the middle of Tibetan Plateau 总被引:1,自引:0,他引:1
Based on a multi-proxy investigation into the deep core of the Cuoe Lake in the middle of Tibetan Plateau, a 2.8 Ma paleoclimatic
and paleoenvironmental evolution is reconstructed. The result of magnetic stratum indicates that the lake basin was formed
at about 2.8 MaBP, while the multi-proxy analyses of lithology, grain size, magnetic susceptibility and geochemical elements
reveal that there have been three major environmental evolution stages and at least two intensive uplifts of the Tibetan Plateau
in the lake basin area, i.e. during 2.8-2.5 MaBP, the lake basin came into being as a result of the disaggregation of the
planation surface and rapid rising of the Tibetan Plateau. During 2.5-0.8 MaBP, with gradual uplift of the Tibetan Plateau,
the environment of this area was more effectively controlled by the climatic cycle of the alternative glacial-interglacial
stages. After 0.8 MaBP, the middle part of the Plateau accelerated its uplift and entered cryoshere. 相似文献
16.
Palaeomonsoon variability in the southern fringe of the Badain Jaran Desert,China, since 130 ka BP 总被引:1,自引:0,他引:1
Quanzhou Gao Zhen Tao Baosheng Li Heling Jin Xueyong Zou Yechun Zhang Guangrong Dong 《地球表面变化过程与地形》2006,31(3):265-283
Taking the Chagelebulu Stratigraphic Profile as a typical example, a comprehensive study has been conducted to elucidate the palaeoclimatic and geomorphic evolution patterns in the southern fringe of the Badain Jaran Desert, which were found to be complex and polycyclic in the past 130 ka. However, the fluctuating magnitude is not as remarkable as that in the eastern China sandy region. The shift in climate from interglacial to glacial and the uplift process of the Qinghai–Xizang Plateau are the two leading forces driving the evolution of the climate and desert landforms in this area. Seventeen cycles of cold, dry and warm, humid climatic stages were recognized in the Upper Pleistocene Series of the profile. The sharp uplift of the Qinghai–Xizang Plateau superimposed a cool and arid climatic trend in this area. As a result of the climatic changes, the desert in this area has undergone multiple stages of expansion and contraction since 130 ka bp . The middle Holocene Epoch and the early stage of the Late Pleistocene Period were the main periods when the sand dunes became stabilized, and the early and late phases of the Holocene Epoch and late phase of the Pleistocene Epoch were the main periods when the previously stabilized sand dunes became mobile. The late phase of the Pleistocene Epoch was the most mobile stage, when the aeolian sand activities formed the essential geomorphic pattern of the Badain Jaran Desert. Copyright © 2005 John Wiley & Sons, Ltd. 相似文献
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跨越中、印、缅三国交界的喜马拉雅“东构造结”地区(92°E~97°E,26°N~30°N)有一半以上的面积尚没有重力测点,是重力数据空白区,故无法直接研究其重力场特征与深部地壳结构(构造).本文应用卫星重力异常资料作为近似空间重力异常,经计算给出的布格重力异常,其特征与该地区的地形高程呈很好的镜像相关.据此得到该区不同方位的3个地壳深部结构剖面.重力异常反演求得青藏高原地壳厚度>70 km;喜马拉雅造山带为55 km左右;布拉马普特拉河谷盆地为33~35 km;那加山山脉地区为40~45 km,即呈现出3个不同构造单元的展布.同时求得“东构造结"区由高密度的刚性物质构成,在印度洋板块的碰撞、挤压作用下呈向北运移,并插入青藏高原东缘.基于这样的构造格局和深层动力过程,导致了青藏高原东南缘和东北缘的强烈构造运动,大、小地震的频频发生和矿产资源的聚集. 相似文献
19.
利用青藏高原46个气象站的最大冻土深度观测资料、中国160个气象站降水资料和NCAR/NCEP资料,对青藏高原冻土的季节性冻融过程进行合成分析,发现青藏高原土壤的季节冻融过程对青藏高原上空及东亚大气环流有显著的影响,在高原最大冻土深度较小的年份中,7月份,南亚高压强且偏西,500hPa印度低压强,西太平洋副热带高压弱且偏东,高原南部的东风较强;最大冻土深度较大的年份,南亚高压弱且偏东,印度低压弱,西太平洋副热带高压强且偏西. 在不同的冻融年份,850hPa上纬向风的差异显著区反映了西南季风的活动. 最大冻土深度与中国夏季(7月份)降水有3条显著相关带,雨带的分布与中国夏季平均雨带相吻合. 由此,青藏高原季节冻融过程引起的水热变化是影响东亚气候的一个重要外源. 相似文献
20.
青海湖水量平衡及水位变化预测 总被引:17,自引:5,他引:12
青海湖是我国最大的内陆湖泊,流域面积29661km~(2),水面高程超过3000m,受人为活动影响相对较少,基本上还处于半自然状态。水量平衡计算结果表明,有观测资料的近30年来,青海湖处于负平蘅状态,水位下降了2.96m,平均每年下降10.2cm。如果未来湖区的气候大体保持过去的情况,水位将再下降5.8m,经过57年才能平衡。如果考虑“温室效应”所引起的西北地区未来气候变化,水位亦将下降,每年平均下降10.1cm。 相似文献