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1.
基于SRTM DEM数据,以青藏高原东缘龙门山地区为研究区域,本文通过条带状剖面分析、古地形面(残余面)恢复以及弹性挠曲模拟等研究手段,计算了青藏高原东缘龙门山地区晚新生代地壳均衡隆升与地表剥蚀之间的定量关系,探讨了龙门山地区表面剥蚀作用与均衡隆升作用之间的地表响应过程,从而为研究青藏高原东缘龙门山地区晚新生代以来的剥蚀—成山作用的隆升机制提供定量依据。研究表明:(1)晚新生代以来龙门山的地表剥蚀量为(0.74~1.14)×105km3;(2)大量的地表剥蚀作用驱动了青藏高原东缘龙门山的地壳均衡反弹,使龙门山隆升了近2 km;(3)龙门山地区地表剥蚀量和均衡隆升量具有空间匹配性,岷山断块及龙门山中、南段的均衡隆升量高于青藏高原东缘其它区域,反映了晚新生代以来龙门山地区在不同分段内差异化的构造地貌形态及与剥蚀—隆升相关的地表过程。(4)龙门山的隆升是多期、多种隆升机制叠加的产物,其隆升过程具有历史性和复合性。均衡隆升和剥蚀作用在相似的时间尺度上和空间尺度上控制着龙门山地貌的形成,约束了青藏高原东缘龙门山的隆升机制。  相似文献   

2.
龙门山褶皱冲断带南北分段性与汶川地震的关系   总被引:3,自引:1,他引:2  
龙门山褶皱冲断带位于青藏高原东缘与四川盆地之间,中生代以来主要经历了晚三叠世和新生代两期重要的地壳缩短变形,形成了典型的逆冲推覆构造带.龙门山的形成和演化与青藏高原隆升以及地震活动有着密切的关系,因此龙门山褶皱冲断带南北两段的差异性被众多学者所关注.文章在前人工作的基础之上从3个角度来阐述龙门山南北两段的差异性:1)地质调查和地震反射剖面解释表明,晚三叠世龙门山北段变形强烈而南段变形不明显,南北分段格局就此形成;2)汶川地震同震地表破裂的差异,北段以右旋斜向逆冲为主,南段则主要以逆冲为主.兼有少量的走滑分量;3)同震断裂的三维构造建模揭示出,同震断层的三维几何形态同样存在南北差异,北段同震断层只有一条且不能向下延伸至深部的主滑脱层,而南段同震断层有两条分支,二者在大约10km的深度合并成一条,并向下延伸至约17km深度与主滑脱层相连.因此,认为汶川地震同震破裂的南北分段性是由于晚三叠世龙门山先存的南北构造差异性所引发的.  相似文献   

3.
李志刚  刘静  贾东  孙闯  王伟  姚文倩 《地质通报》2016,35(11):1829-1844
2008年汶川地震(Mw 7.9)同震滑移结果表明,今地壳缩短为近EW向,与龙门山褶皱冲断带斜交。这一斜向逆冲作用的准确起始时间一直未得到很好的约束。基于龙门山南段山前大邑背斜区三维地震解释和构造建模,结合野外地质调查和年代学数据,确定了晚新生代存在NE向和近NS向2期构造变形。120km长的NS向构造切割了NE向构造,表明近NS向构造形成时间较晚。山前大邑和邛西背斜区近NS向断层和褶皱的活动,均反映了龙门山南段局部或区域上水平最大主应力方向的转换过程,渐新世—早上新世的NW—SE向转变为晚上新世—全新世的近EW向。龙门山南段山前发育的NS向构造和汶川地震同震变形均反映出青藏高原东缘最新的EW向地壳缩短过程,为理解青藏高原东缘的隆升机制提供了新的视角。  相似文献   

4.
青藏高原东缘新构造及其对汶川地震的控制作用   总被引:21,自引:3,他引:18       下载免费PDF全文
张岳桥  杨农  施炜  董树文 《地质学报》2008,82(12):1668-1678
基于卫星遥感图像解译、地形起伏度分析和地面调查资料,论述了青藏高原东缘构造地貌格局、新构造演化阶段和活动断裂特征,提出青藏高原东缘不同地块在晚新生代时期有序的向东挤出过程,并划分为4个阶段:中新世早期川滇地块向北东挤出、中新世晚期川滇地块的再次强烈向东挤出、上新世至早中更新世时期川青地块的向东挤出、晚更新世以来最新构造变动阶段,青藏高原东缘地貌边界带也经历了由西向东、由南向北的有规律的迁移过程。基于活动构造的最新研究成果和现今GPS测量成果,阐述了东昆仑岷山龙门山走滑逆冲断裂系统的运动学特征。根据地震破裂构造的实地调查,分析了汶川地震的地表破裂行为,提出了汶川地震的发震构造模型。研究认为,青藏高原东部地区NW向楔状条块向东运动速度的一半被鲜水河断裂及其北西延伸的构造带所吸收,而龙门山构造带向东运动受阻于四川盆地之下扬子刚性地块,使得龙门山断裂带处在低应变、高应力环境下,因长期应力应变累积而导致向西陡倾的断裂带突然向东逆冲运动而释放能量。汶川强震发生的深部机理值得深入研究。  相似文献   

5.
本文以青藏高原东缘的三级地貌(川西高原、龙门山和四川盆地)单元为基础,利用裂变径迹定年数据分区块研究了该地区的晚新生代以来的剥蚀速率。研究结果表明,晚白垩世以来青藏高原东缘经历了一个由平缓到突然加速的剥蚀过程,其转折点为中新世。在整个时间段内的平均剥蚀速率,川西高原为0.26mm/yr,龙门山为0.72mm/yr,四川盆地为0.20mm/yr。龙门山的剥蚀速率大约是川西高原的2.8倍,间接反映边缘山脉的隆升并不等同于高原内部的隆升,边缘山脉的隆升可能是构造隆升和剥蚀隆升相叠加的结果。  相似文献   

6.
印支期龙门山断裂带的逆冲-推覆构造和沉积响应   总被引:1,自引:0,他引:1  
伴随着华南、华北和羌塘地块在中—晚三叠世的俯冲—碰撞,古特提斯洋逐渐消亡,在龙门山及其前陆盆地发生了广泛的构造和沉积事件,统称为印支造山运动。然而,这期重要的造山事件普遍叠加有新生代印度与欧亚板块俯冲碰撞所引起的相似的北西—南东向构造挤压作用,使得印支期的构造活动对奠定龙门山初始构造和地貌特征,乃至对新生代构造活动的深远影响难以区分。对青藏高原其他边界的研究表明,只有通过多种手段从多个角度才能认清造山带形成的真实历史,而近些年来在龙门山地区开展的深地震探测、主断裂和飞来峰定年、前陆盆地沉积序列和沉积作用以及大地热流分布的研究则为我们进一步揭示印支初期龙门山断裂带构造活动本质提供了全新的视角。深地震反射剖面和最新的定年结果揭示龙门山地区在印支期发生了大型逆冲—推覆作用,在此期间,形成了两条主要断裂带,并直至后碰撞造山时期,形成了多期次的山前飞来峰构造。龙门山断裂带在印支期的大型逆冲—推覆构造活动,引发了大量的陆源碎屑沉积物涌入到四川前陆盆地中。强烈的断裂活动还引发了区域大地震的发生,在四川盆地西缘未完全固结沉积地层中形成了软沉积物变形。综合以往的研究结果,我们认为龙门山早期的逆冲—推覆和青藏高原东缘大地热流的升高伴随有区域岩石圈底部的拆沉导致软流圈高温物质的上涌。这种早期的构造格局对龙门山断裂带在新生代构造地貌的最终形成产生了深远的影响。  相似文献   

7.
龙门山晚新生代均衡反弹隆升的定量研究   总被引:1,自引:0,他引:1  
龙门山位于青藏高原东缘与四川盆地的交接部位,是青藏高原周边山脉中地形梯度变化最大的山脉,其隆升过程和机制一直是国际地学界关注的焦点。晚新生代经过大量的滑坡、泥石流等快速剥蚀作用,龙门山的高程却不断升高。讨论了龙门山构造隆升的3种地球动力学机制,即下地壳通道流机制、地壳挤压缩短变形机制、地壳均衡反弹机制。晚新生代龙门山的隆升与剥蚀引起的均衡反弹作用相关,剥蚀作用使得地壳岩石逐步被移去,剥蚀区重力损失,岩石圈或地壳卸载作用导致山脉顶峰的隆升。结合数字高程模型数据研究表明,巨大地震的长期同震构造变形以及滑坡、泥石流等引起的快速剥蚀所导致的地壳均衡反弹,可能是龙门山晚新生代构造隆升的地球动力学新机制。龙门山地区现今高程受构造作用与剥蚀引起的均衡反弹作用的共同影响,其中剥蚀引起的均衡反弹作用对龙门山隆升的影响贡献率约占30%。  相似文献   

8.
龙门山断裂带隆起造山独特性探讨   总被引:1,自引:0,他引:1       下载免费PDF全文
龙门山断裂带位于四川盆地西缘;青藏高原东部;为四川盆地与松潘-甘孜地块的接触构造边界。龙门山地区海拔从东侧100 km外四川盆地的500 m突升至3 000 m高度;明显地标注了青藏高原的东部边界;其隆升机制也引起了国内外地质工作者的广泛兴趣;并且提出了多种隆升机制模型。在本次研究中;我们利用SinoProbe-02深反射地震剖面数据对龙门山地区的隆升机制进行研究;从而进一步探讨龙门山地区隆起造山的独特性;并讨论其与传统意义中的造山带的区别;认为龙门山断裂造山带为板块内部构造活动引起岩石圈隆起所形成的。本文的研究结果将使我们更深刻地了解龙门山地区的构造活动特点;并且有助于了解青藏高原东缘对印度-欧亚板块碰撞的构造响应。  相似文献   

9.
李勇  ALDENSMORE  周荣军  MA  ELLIS 《地质学报》2005,79(5):608-615
龙门山是青藏高原东缘边界山脉,具有青藏高原地貌、龙门山高山地貌和山前冲积平原三个一级地貌单元。利用数字高程模式图像和裂变径迹年代测定方法研究和计算龙门山晚新生代剥蚀厚度与剥蚀速率,结果表明:3.6 Ma以来龙门山的剥蚀厚度介于1.91-2.16 km之间,剥蚀速率介于0.53-0.60 mm/a之间。在此基础上,开展了该地区岩石圈的弹性挠曲模拟,结果表明龙门山的隆升机制具有以构造缩短隆升和剥蚀卸载隆升相叠合的特点。3.6 Ma之前,龙门山的隆升与逆冲推覆构造负载有关,以构造缩短驱动的构造隆升为特色;3.6 Ma之后,龙门山的隆升与剥蚀卸载驱动的抬升有关,并以剥蚀卸载隆升为特色,进而提出了龙门山晚新生代以来的隆升机制以剥蚀成山作用为主的认识。  相似文献   

10.
龙门山前陆褶皱冲断带构造解析与川西前陆盆地的发育   总被引:57,自引:2,他引:55  
通过详细的野外地质调查和精细的地震剖面构造解析。揭示了龙门山前陆褶皱冲断带的基本构造特征。对比分析了龙门山北段与南段构造变形几何学和运动学的差异。提出龙门山北段主要表现为一系列复杂的逆冲推覆构造,晚三叠纪变形强于新生代;龙门山南段则以基底卷入的叠瓦状冲断为特点,晚白垩纪-早第三纪变形尤为突出。与前陆褶皱冲断带相对应的是,川西晚三叠纪时期的周缘前陆盆地主要表现在整个龙门山褶皱冲断带的前渊地区;而晚白垩纪-早第三纪再生前陆盆地却局限在川西盆地的南部,并且印-藏碰撞的持续挤压作用使得晚新生代构造变形不断向东扩展进入川西盆地南部。  相似文献   

11.
The Longmen Shan region includes, from west to east, the northeastern part of the Tibetan Plateau, the Sichuan Basin, and the eastern part of the eastern Sichuan fold-and-thrust belt. In the northeast, it merges with the Micang Shan, a part of the Qinling Mountains. The Longmen Shan region can be divided into two major tectonic elements: (1) an autochthon/parautochthon, which underlies the easternmost part of the Tibetan Plateau, the Sichuan Basin, and the eastern Sichuan fold-and-thrust belt; and (2) a complex allochthon, which underlies the eastern part of the Tibetan Plateau. The allochthon was emplaced toward the southeast during Late Triassic time, and it and the western part of the autochthon/parautochthon were modified by Cenozoic deformation.

The autochthon/parautochthon was formed from the western part of the Yangtze platform and consists of a Proterozoic basement covered by a thin, incomplete succession of Late Proterozoic to Middle Triassic shallow-marine and nonmarine sedimentary rocks interrupted by Permian extension and basic magmatism in the southwest. The platform is bounded by continental margins that formed in Silurian time to the west and in Late Proterozoic time to the north. Within the southwestern part of the platform is the narrow N-trending Kungdian high, a paleogeographic unit that was positive during part of Paleozoic time and whose crest is characterized by nonmarine Upper Triassic rocks unconformably overlying Proterozoic basement.

In the western part of the Longmen Shan region, the allochthon is composed mainly of a very thick succession of strongly folded Middle and Upper Triassic Songpan Ganzi flysch. Along the eastern side and at the base of the allochthon, pre-Upper Triassic rocks crop out, forming the only exposures of the western margin of the Yangtze platform. Here, Upper Proterozoic to Ordovician, mainly shallow-marine rocks unconformably overlie Yangtze-type Proterozic basement rocks, but in Silurian time a thick section of fine-grained clastic and carbonate rocks were deposited, marking the initial subsidence of the western Yangtze platform and formation of a continental margin. Similar deep-water rocks were deposited throughout Devonian to Middle Triassic time, when Songpan Ganzi flysch deposition began. Permian conglomerate and basic volcanic rocks in the southeastern part of the allochthon indicate a second period of extension along the continental margin. Evidence suggests that the deep-water region along and west of the Yangtze continental margin was underlain mostly by thin continental crust, but its westernmost part may have contained areas underlain by oceanic crust. In the northern part of the Longmen Shan allochthon, thick Devonian to Upper Triassic shallow-water deposits of the Xue Shan platform are flanked by deep-marine rocks and the platform is interpreted to be a fragment of the Qinling continental margin transported westward during early Mesozoic transpressive tectonism.

In the Longmen Shan region, the allochthon, carrying the western part of the Yangtze continental margin and Songpan Ganzi flysch, was emplaced to the southeast above rocks of the Yangtze platform autochthon. The eastern margin of the allochthon in the northern Longmen Shan is unconformably overlapped by both Lower and Middle Jurassic strata that are continuous with rocks of the autochthon. Folded rocks of the allochthon are unconformably overlapped by Lower and Middle Jurassic rocks in rare outcrops in the northern part of the region. They also are extensively intruded by a poorly dated, generally undeformed belt, of plutons whose ages (mostly K/Ar ages) range from Late Triassic to early Cenozoic, but most of the reliable ages are early Mesozoic. All evidence indicates that the major deformation within the allochthon is Late Triassic/Early Jurassic in age (Indosinian). The eastern front of the allochthon trends southwest across the present mountain front, so it lies along the mountain front in the northeast, but is located well to the west of the present mountain front on the south.

The Late Triassic deformation is characterized by upright to overturned folded and refolded Triassic flysch, with generally NW-trending axial traces in the western part of the region. Folds and thrust faults curve to the north when traced to the east, so that along the eastern front of the allochthon structures trend northeast, involve pre-Triassic rocks, and parallel the eastern boundary of the allochthon. The curvature of structural trends is interpreted as forming part of a left-lateral transpressive boundary developed during emplacement of the allochthon. Regionally, the Longmen Shan lies along a NE-trending transpressive margin of the Yangtze platform within a broad zone of generally N-S shortening. North of the Longmen Shan region, northward subduction led to collision of the South and North China continental fragments along the Qinling Mountains, but northwest of the Longmen Shan region, subduction led to shortening within the Songpan Ganzi flysch basin, forming a detached fold-and-thrust belt. South of the Longmen Shan region, the flysch basin is bounded by the Shaluli Shan/Chola Shan arc—an originally Sfacing arc that reversed polarity in Late Triassic time, leading to shortening along the southern margin of the Songpan Ganzi flysch belt. Shortening within the flysch belt was oblique to the Yangtze continental margin such that the allochthon in the Longmen Shan region was emplaced within a left-lateral transpressive environment. Possible clockwise rotation of the Yangtze platform (part of the South China continental fragment) also may have contributed to left-lateral transpression with SE-directed shortening. During left-lateral transpression, the Xue Shan platform was displaced southwestward from the Qinling orogen and incorporated into the Longmen Shan allochthon. Westward movement of the platform caused complex refolding in the northern part of the Longmen Shan region.

Emplacement of the allochthon flexurally loaded the western part of the Yangtze platform autochthon, forming a Late Triassic foredeep. Foredeep deposition, often involving thick conglomerate units derived from the west, continued from Middle Jurassic into Cretaceous time, although evidence for deformation of this age in the allochthon is generally lacking.

Folding in the eastern Sichuan fold-and-thrust belt along the eastern side of the Sichuan Basin can be dated as Late Jurassic or Early Cretaceous in age, but only in areas 100 km east of the westernmost folds. Folding and thrusting was related to convergent activity far to the east along the eastern margin of South China. The westernmost folds trend southwest and merge to the south with folds and locally form refolded folds that involve Upper Cretaceous and lower Cenozoic rocks. The boundary between Cenozoic and late Mesozoic folding on the eastern and southern margins of the Sichuan Basin remains poorly determined.

The present mountainous eastern margin of the Tibetan Plateau in the Longmen Shan region is a consequence of Cenozoic deformation. It rises within 100 km from 500–600 m in the Sichuan Basin to peaks in the west reaching 5500 m and 7500 m in the north and south, respectively. West of these high peaks is the eastern part of the Tibetan Plateau, an area of low relief at an elevations of about 4000 m.

Cenozoic deformation can be demonstrated in the autochthon of the southern Longmen Shan, where the stratigraphic sequence is without an angular unconformity from Paleozoic to Eocene or Oligocene time. During Cenozoic deformation, the western part of the Yangtze platform (part of the autochthon for Late Triassic deformation) was deformed into a N- to NE-trending foldandthrust belt. In its eastern part the fold-thrust belt is detached near the base of the platform succession and affects rocks within and along the western and southern margin of the Sichuan Basin, but to the west and south the detachment is within Proterozoic basement rocks. The westernmost structures of the fold-thrust belt form a belt of exposed basement massifs. During the middle and later part of the Cenozoic deformation, strike-slip faulting became important; the fold-thrust belt became partly right-lateral transpressive in the central and northeastern Longmen Shan. The southern part of the fold-thrust belt has a more complex evolution. Early Nto NE-trending folds and thrust faults are deformed by NW-trending basementinvolved folds and thrust faults that intersect with the NE-trending right-lateral strike-slip faults. Youngest structures in this southern area are dominated by left-lateral transpression related to movement on the Xianshuihe fault system.

The extent of Cenozoic deformation within the area underlain by the early Mesozoic allochthon remains unknown, because of the absence of rocks of the appropriate age to date Cenozoic deformation. Klippen of the allochthon were emplaced above the Cenozoic fold-andthrust belt in the central part of the eastern Longmen Shan, indicating that the allochthon was at least partly reactivated during Cenozoic time. Only in the Min Shan in the northern part of the allochthon is Cenozoic deformation demonstrated along two active zones of E-W shortening and associated left-slip. These structures trend obliquely across early Mesozoic structures and are probably related to shortening transferred from a major zone of active left-slip faulting that trends through the western Qinling Mountains. Active deformation is along the left-slip transpressive NW-trending Xianshuihe fault zone in the south, right-slip transpression along several major NE-trending faults in the central and northeastern Longmen Shan, and E-W shortening with minor left-slip movement along the Min Jiang and Huya fault zones in the north.

Our estimates of Cenozoic shortening along the eastern margin of the Tibetan Plateau appear to be inadequate to account for the thick crust and high elevation of the plateau. We suggest here that the thick crust and high elevation is caused by lateral flow of the middle and lower crust eastward from the central part of the plateau and only minor crustal shortening in the upper crust. Upper crustal structure is largely controlled in the Longmen Shan region by older crustal anisotropics; thus shortening and eastward movement of upper crustal material is characterized by irregular deformation localized along older structural boundaries.  相似文献   

12.
文章利用数字高程剖面将青藏高原东缘分为4个大尺度地貌单元,即青藏高原地貌区、龙门山高山地貌区、山前冲积平原区(成都盆地)和四川盆地东部隆起区。根据数字高程剖面中的最高海拔高程点剖面与最低海拔高程点剖面之间的高差,定量计算了该地区河流下切深度;结合成都盆地岷江最古老冲积扇沉积物提供的青藏高原东缘河流形成的时间(3.6MaB.P.),定量计算了河流下切速率为1.29mm/a;在约束局部侵蚀基准面和气候变化对河流下切速率控制作用的基础上,建立了青藏高原东缘河流下切速率与表面隆升速率之间的定量关系,结果表明河流下切速率约为表面隆升速率的4倍。基于龙门山在表面隆升速率和下切速率等方面均大于青藏高原内部,认为青藏高原东缘的边缘山脉是剥蚀隆升和构造隆升两者叠加的产物。  相似文献   

13.
樊春  王二七  王刚  王世锋 《地质科学》2008,43(3):417-433
龙门山断裂带位于青藏高原东缘,构成了青藏高原和四川盆地的重要构造边界。近年来的研究表明:在新生代晚期,除了存在逆冲推覆之外,龙门山的中段和南段还发生了明显的右行走滑活动。对龙门山北段的青川断裂进行的系统研究发现:断裂具有明显的右行走滑特征,沿断裂发育大量不同规模的水系位错,其中嘉陵江水系位错规模最大,据此可确定青川断裂的最大位移量为17km。进一步的野外工作证实断裂的走滑位移在尾端发生构造变换,位于断裂南西端的轿子顶穹隆是叠加构造,吸收了青川断裂的部分位移量;位于断裂北东端的汉中盆地则是处于伸展应力环境下的断陷盆地,吸收了其大部分位移量。  相似文献   

14.
青藏高原东缘晚新生代大邑砾岩的 物源分析与水系变迁*   总被引:2,自引:4,他引:2  
成都盆地晚新生代碎屑沉积物的快速堆积是青藏高原东缘强烈隆升的产物,同时为青藏高原东缘晚新生代的隆升提供了强有力的证据。文章以盆地底部的大邑砾岩作为研究切入点,详细研究了它的物源区,以深化对青藏高原东缘晚新生代隆升过程的理解。通过砾石成分统计、砂岩薄片鉴定、重矿物分析以及古流向恢复等方面的研究表明,成都盆地北部和南部的大邑砾岩分别受不同的物源区和河流所控制。其中北部的大邑砾岩受控于出口在都江堰南约4km处向南流的河流所控制,其物源区为玉堂镇以西、汶川-茂汶断裂以东的流域范围内。而南部的大邑砾岩则主要受向东流的古青衣江的控制,其物源区即为现代青衣江流域。大邑砾岩的物源分析表明晚新生代期间岷江和青衣江都曾发生河流改道。  相似文献   

15.
川西高原主要地质灾害特征及其影响因素浅析   总被引:5,自引:1,他引:5       下载免费PDF全文
川西高原位于青藏高原东缘,是崩塌、滑坡和泥石流等突发性地质灾害的群发地,具有分布基本沿活动构造带走向、发生时间较集中、人类活动诱发的地质灾害数量增多和地质灾害链后果严重等特点,主要受地质构造、现今构造运动、地形地貌、降雨及人类不科学的社会、经济和工程活动等多种因素影响。  相似文献   

16.
准噶尔盆地南缘中-新生界碎屑成份特征与构造期次   总被引:4,自引:4,他引:4  
准噶尔盆地南缘晚侏罗世-早白垩世早期、晚白垩世及晚新生代发育的近源粗碎屑沉积显示构造活动的存在。野外剖面及镜下碎屑成份统计表明:砾岩的砾石成份、砂岩碎屑成份的物源属性主要是再旋回造山带和晚古生代的岩浆弧,但盆地南缘东段与西段的岩屑组成及物源属性存在较大的差异。其中,沉积岩岩屑在晚侏罗世—早白垩世早期、晚白垩世和晚新生代发生了相应的增加,显示盆缘沉积岩物源的隆升—剥蚀作用和构造活动的相对活跃。砂岩碎屑特征、重矿物相对含量及重矿物组合特征证明盆地南缘东、西两段的物源属性存在较大差异,特别是不稳定重矿物的增加显示晚侏罗世-早白垩世早期、晚白垩世和晚新生代为构造相对活跃的构造环境。综合中-新生界沉积碎屑特征及差异分析,准噶尔盆地南缘中-新生代盆山格局发生了3次较大的转变过程,分别对应于上述3个时期。中-新生代3次构造活动对含油气系统形成具有重要控制作用,构造活动期次与油气藏形成、调整的期次也有良好的对应关系。  相似文献   

17.
DEFORMATIONAL AND METAMORPHIC HISTORY OF THE CENTRAL LONGMEN MOUNTAINS, SICHUAN CHINA1 ArneDC ,WorleyBA ,WilsonCJL ,etal.Differentialexhumationinresponsetoepisodicthrustingalongtheeasternmar ginoftheTibetanPlateau[J] .Tectonophysics,1997,2 80 :2 39~ 2 56 . 2 ChenSF ,WilsonCJL ,WorleyBA .TectonictransitionfromtheSongpan GarzeFoldBelttotheSichuanBasin,south westernChina[J] .BasinResearch ,1995,7:2 35~ 2 53. 3 ChenSF ,WilsonCJL .Emplaceme…  相似文献   

18.
Investigation of the deep geophysical structure of the Longmen Mountains tectonic belt and its relation to the Wenchuan Earthquake is important for the study of earthquakes. By using magnetotelluric sounding profiles of the Luqu–Zhongjiang and Anxian–Suining; seismic sounding profiles of the Sichuan Maowen–Chongqing Gongtan, the Qinghai Huashi Gorge–Sichuan Jianyang, and the Batang–Zizhong; and magnetogravimetric data of the Longmen Mountains region, the deep geophysical structure of the Songpan–Ganzi block, the western Sichuan foreland basin, and the Longmen Mountains tectonic belt and their relation was discussed. The eastward extrusion of the Qinghai–Tibet Plateau thrusts the Songpan–Ganzi block upon the Yangtze block, which obstructs the eastward movement of the Qinghai–Tibet Plateau. The Maoxian–Wenchuan, Beichuan–Yingxiu, and Anxian–Guanxian faults of the Longmen Mountains fault belt dip to northwest with different dip angles and gradually converge in the deeper parts. Geophysical structure suggests that an intracrustal low-velocity, low-resistivity, and high-conductivity layer is common between the middle and upper crust west of the Longmen Mountains tectonic belt but not in the upper Yangtze block. The Sichuan Basin has a thick low-resistance sedimentary layer on a stable high-resistance basement; moreover, there are secondary paleohighs and depression structures at the lower part of the western Sichuan foreland basin with characteristic of high magnetic anomalies, whereas the Songpan–Ganzi block has a high resisitivity cover of upper crust and continues to a low-resistance layer. Considering the Longmen Mountains tectonic belt as the boundary, there are Bouguer gravity anomalies of "one belt between two zones." Thus, we infer that there is a corresponding relation between the inferred crystalline basement of the Songpan block and the underlying basin basement of the Longmen Mountains fault belt. Furthermore, there may be an extensive ancient Yangtze block, which is west of the Ruoergai block. In addition, the crust–mantle ductile shear zone under the Longmen Mountains tectonic belt is the main fault, whereas the Beichuan–Yingxiu and Anxian–Guanxian faults at the surface are earthquake faults. The Wenchuan Ms 8.0 earthquake might be attributed to the collision of the Yangtze block and the Qinghai–Tibet Plateau. The eastward obduction of the eastern edge of the Qinghai–Tibet Plateau and eastward subduction of its deeper part under the influence of the collision of the Indian, Pacific, and Philippine Plates with the Eurasia Plate might have caused the Longmen Mountains tectonic belt to cut the Moho and extend to the middle and upper crust; thus, creating high stress concentration and rapid energy release zone.  相似文献   

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