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帕米尔东北侧地壳结构研究 总被引:50,自引:17,他引:50
1998年在帕米尔东北侧伽师及其周边地区完成了两条深地震宽角反射/折射剖面. 结果表明,西昆仑、塔里木和天山在地壳速度结构、构造特征上显示出较大差异. 塔里木块体具有稳定地块的地壳结构特征,地壳平均速度较高(6.5km/s). 向南进入西昆仑,地壳明显增厚,厚度可达0km左右,且地壳平均速度偏低(6.0-6.2km/s),偏低的地壳平均速度主要来源于相对低速度的下地壳结构,反映了西昆仑褶皱系下地壳介质的特征. 向北进入天山后,地壳同样明显增厚,但增厚的程度低于西昆仑下,约为50-55km. 天山地壳同样具有明显低的平均速度(6.2km/s),显示了天山地壳相对"软"的特征,但天山地壳偏低的平均速度来源于广泛分布于中地壳的低速度层和速度偏低的下地壳. 在印度块体向北强烈推挤的作用下,该区地壳遭受强烈的不均匀变形,塔里木块体向南插入西昆仑下,向北插入天山下,形成了该区强烈地震频繁发生的深部构造环境. 相似文献
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以中国西北地区的地震层析成像为基础,研究了天山地震带深部结构的基本特征.结果表明,天山地震带的地壳中部为低速的韧性滑脱层,南天山的断裂深度超过莫霍面,北天山的断裂深度一般只到地壳中部;天山莫霍面的深度一般大于50km,壳-幔边界由宽而缓的速度过渡带构成,中强地震主要位于盆山边界地壳中下部位波速变化较大的区域.帕米尔、南天山和塔里木之间存在一个北北东方向的低速带,乌恰和伽师地震分别位于该低速带东、西两侧的梯度带附近.推测帕米尔、南天山和塔里木之间的相对运动是导致低速带内部物质发生形变并在边界附近产生破裂的主要原因,地幔热物质的侵入对该地区的构造活动起到了重要的动力学作用. 相似文献
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中国西部地区是地震活动十分强烈的地区,天山、阿尔泰、帕米尔和西昆仑都是著名的地震构造带,在这些地震构造带和周边地区发生了多次震级大于5级的强震.本文通过分析西部地区的重力场特征,根据重力数据结合地震剖面、应用Parker-Oldenburg方法反演得到了研究区莫霍面深度,通过对比地震层析成像的反演结果,分析了研究区的地壳结构特征.计算结果表明,研究区地壳结构不均匀特征明显,在造山带地区一般是莫霍面坳陷区,盆地则是莫霍面隆起区,主要造山带地壳速度结构表现为高速区,盆地和主要凹陷区为低速区.根据计算结果和以往强震震中位置分析了地壳构造与强震活动的相关性,西部地区的地震活动与地壳结构的横向不均匀密切相关,强震主要发生在地壳速度变化带附近和地壳速度结构差异较大的地区,在构造应力作用下,这些地壳介质非均匀地区易发生强震,这是中国西部造山带和盆-山边界附近频发强震的构造原因之一. 相似文献
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通过对帕米尔东北侧伽师及其周边地区两条深地震测深剖面S波资料的处理计算,结合P波研究结果,得到了S波二维地壳速度结构和波速比(vP/vS)分布.研究表明:① 塔里木块体平均地壳波速比明显高于西昆仑和天山褶皱带,显示了坚硬、稳定地壳物性特征.下地壳正常偏低的波速比(泊松比)值,说明塔里木块体的下插是该地区地壳运动的主要特征;② 天山褶皱带上地壳岩层相对较软,易于在应力作用下断裂破碎和应力能量释放,是其小震密集分布的重要构造因素;③ 伽师附近正处在下地壳C界面和壳幔边界的上隆顶部或拐点上,是强震群发生的深部构造背景.上地壳中下部的块体边界附近波速比值的交错变化和接触面复杂形态的存在,形成了伽师强震群出现的特殊构造环境.震源处波速比相对较高,剪切模量较小,可能是伽师强震群应力降偏低的主要原因. 相似文献
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南天山及塔里木北缘构造带位于帕米尔地区东北侧,地震活动强烈。文中通过地质构造剖面、深部探测资料和地震震源机制解资料,综合研究了该区的地震构造模型。结果认为,该区的构造活动主要表现为天山地块逆冲于塔里木地块之上。天山构造系统包括迈丹断裂及其前缘推覆构造;塔里木构造系统包括深部的塔里木北缘断裂、基底共轭断层和浅部的推覆构造。塔里木北缘断裂是发育于塔里木地壳内部的高角度断裂,其形成原因在于塔里木和天山构造变形方向的差异。塔里木北缘断裂为研究区大地震的主要发震构造,天山推覆构造和塔里木基底断裂系统均具有不同性质的中强地震发震能力 相似文献
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利用地震层析成像法建立起天山和邻近区域的地壳上地幔三维速度图象, 结果表明:(1)北天山和天山中部地区为隆起的高速地区, 吐鲁番盆地、库车拗陷、柯坪断块、喀什拗陷和准噶尔盆地南缘构成了天山北南两侧的山前低速区。伊犁盆地和西昆仑是壳内稳定的高速块体, 巴楚隆起一直延伸到地壳的底部。沿天山主峰和西昆仑公格尔一带, 莫霍面形成五大低速区;(2)北天山和准噶尔西部岩石圈厚度较大, 具有高速特性, 在其顶部80km左右可能存在较流物质。天山南部岩石圈的性质不明显, 喀什地区位置120-280km之间存在的低速锥形体估计与地幔软流物质的上涌有关;(3)速度结构与地震活动的确存在着一定的联系, 特别是上地壳低速区与下地壳高速区之间的梯度带往往与强震的分布有关, 有可能成为中强地震的孕育场所;(4)天山南北缘的地震多发地带是壳内介质结构极不均匀的地区, 也是深大断裂较为发育的区域, 在外力的作用下很容易产生破裂或层间滑动而引发地震。 相似文献
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本文利用重力数据采用Parker-Oldenburg方法反演了南北构造带及邻域地区的地壳厚度,同时采用体波地震层析成像方法反演了研究区的地壳至上地幔的三维速度结构.根据计算结果对研究区的地壳及岩石层结构进行了探讨,力图揭示南北构造带及邻域地壳、岩石层变形特征,并且对青藏高原边缘活动带壳幔构造演化的深部成因、研究区的上地幔流变性及其动力学意义进行了相应的讨论.通过分析研究表明南北构造带地区为地壳厚度剧变区,西侧为地壳增厚区,东侧的鄂尔多斯、四川盆地为地壳稳定区,而再向东为地壳逐渐减薄区.中国岩石层减薄与增厚的边界基本被限定在大兴安岭—太行山—秦岭—大巴山—武陵山一带,这也是东部陆缘带和中部扬子、鄂尔多斯克拉通地区深部构造边界的分界线,其两侧不仅浅层地质构造存在较大的差异,上地幔深部的物性状态和热活动也明显不同,这说明研究区的岩石层和软流层结构以及深部物质的分布存在横向非均匀性.中部地区和青藏高原深部构造边界的分界线位于东经100°—102°左右. 相似文献
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青藏高原-天山大陆内部地壳变形三维数值模拟研究 总被引:1,自引:0,他引:1
大量研究事实证明,板块相互作用除了在板块边缘产生地壳强烈变形外,其应变可以扩展到远离板块边界的大陆内部,对板块相互作用的远程效应以及大陆内部地壳变形的动力学机制目前仍然有争议.本文结合前人对大陆岩石圈流变学研究的知识和现代GPS观测结果,应用三维有限元数值模拟技术探讨了印度大陆向北推挤与青藏高原-天山地壳变形的动力学关系.模拟地壳的流变学用Maxwell黏弹性模型近似,印-藏的汇聚速度用大量GPS观测的速度边界约束,而欧亚大陆内的远程边界用弹簧约束.在重力方向上,模型考虑了重力加载和位于深部的静岩压力边界.通过大量模型的计算,在均一的地壳流变学框架下印-藏汇聚的应变使研究区内发生整体隆升;然而当考虑青藏高原,塔里木地块和天山等区域中地壳流变学可能存在的横向不一致时,可以发现印藏汇聚的应变经青藏高原吸收后可以跃过塔里木导致天山地区的强烈变形.这暗示新生代以来发生在天山地区强烈地壳变形的动力学可能与印-藏汇聚过程中青藏高原-塔里木天山一带岩石圈流变学存在横向不均一有关.这对我们进一步认识板块相互作用的远程效应和大陆内部岩石圈变形机制有一定理论意义 相似文献
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横跨西昆仑-塔里木接触带的爆炸地震探测 总被引:15,自引:2,他引:13
横跨西昆仑与塔里木接触带的爆炸地震宽角反射剖面,揭示了青藏高原北缘陆-陆碰撞带的深部地壳结构.剖面图显示,塔里木盆地的结晶基底与Moho面产状一致,整个地壳似厚板状向南倾,倾角 5℃-7℃,在塔里木南部 150 km的距离上, Moho面 深度由 40 km增加到 57 km.展现了一幅塔里木向西昆仑山下俯冲的几何图像.西昆仑 北坡的地壳结构具有明显的受挤压缩短的特征:基底抬升,界面北倾,Moho面突然抬 起并变平,下地壳厚达 20 km. 相似文献
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(胥颐,朱介寿,刘志坚,张华卿,朱燕)3-DvelocityimagesofthecrustanduppermantleoftheTianshanarea¥YiXU;Jie-ShouZHU;Zhi-JianLIU;Hua-QingZHANGandYa... 相似文献
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Tian Qinjian 《中国地震研究》2007,21(1):74-84
The interaction zone between southern Tianshan and northern Tarim is located at the northeast side of Pamir. It is a region with high seismicity. We constructed a seismotectonic model for the west part of this zone from geological profiles, deep crust seismic detection and earthquake focal mechanisms data. Based on the synthesized geological features, deep crust structure, and earthquake focal mechanisms, we think that the main regional tectonic feature is that the Tianshan tecto-lithostratigraphic unit overthrusts on the Tarim block. The Tianshan tectonic system includes the Maidan fault and thrust sheets in front of the fault; The Tarim tectonic system includes the underground northern Tarim margin fault, conjugate faults in basement and overthrust fault in shallow. The northern Tarim margin fault is a high angle fault deep in the Tarim crust, adjusting different trending deformation between Tianshan and Tarim. It is a major active fault that can generate large earthquakes. The other faults, such as the Tianshan overthrust system and the Tarim basement faults in this area may generate moderately strong earthquakes with different styles. 相似文献
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中国境内天山地壳上地幔结构的地震层析成像 总被引:23,自引:5,他引:18
根据横跨中国境内天山的库车—奎屯宽频带流动地震台阵和区域地震台网记录的近震和远震P波走时数据,利用地震层析成像方法重建了沿该地震台阵剖面下方400 km深度范围内地壳上地幔的P波速度结构.结果表明:沿新疆库车—奎屯剖面,天山地壳具有明显的横向分块结构,且南、北天山地壳显示了较为强烈的横向变形特征,表明塔里木地块对天山地壳具有强烈的侧向挤压作用;在塔里木和准噶尔地块上地幔顶部有厚度约60~90 km的高速异常体,塔里木—南天山下方的高速异常体产生了较为明显的弯曲变形,而准噶尔—北天山下方的高速异常体向南一直俯冲到中天山南侧边界下方300 km的深度,两者形成了不对称对冲构造;在塔里木和准噶尔地块下方150~400 km深度存在上地幔低速体,其中塔里木地块一侧的上地幔低速物质上涌到南天山地块的下方;在塔里木—南天山200~300 km深度范围的上地幔存在高速异常体,它可能是地幔热物质向上迁移过程融断的塔里木岩石圈的拆离体. 上述结果表明,塔里木地块的俯冲可能涉及整个岩石圈深度,但其前缘仅限于南天山的北缘;青藏高原隆升的远程效应可能不但驱动塔里木岩石圈向北俯冲,同时还造成天山造山带南侧上地幔物质的涌入;天山造山带上地幔广泛存在的低速异常有助于其上地幔的变形,而上地幔物质的强烈非均匀性应有助于推动天山造山带上地幔小尺度地幔对流的形成;根据研究区地壳上地幔速度结构特征推断,新近纪以来天山快速隆升的主要力源来自青藏高原快速隆升的远程效应,相对软弱的上地幔为加速天山造山带的变形和隆升创造了必要条件. 相似文献
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A study on physical property of crustal ma—terial and seismogenic environment in northeastern Pamir 总被引:1,自引:0,他引:1
2-D crustal structure and velocity ratio are obtained by processing S-wave data from two wide-angle reflec-tion/refraction profiles in and around Jiashi in northeastern Pamir,with the result of P-wave data taken into con-sideration.The result shows that:1)Average crustal velocity ratio is obviously higher in Tarim block than in West Kunlun Mts.and Tianshan fold zone,which reflects its crustal physical property of “hardness“and stability.The relatively low but normal velocity ratio(Poisson‘s ratio)of the lower crust indicates that the “downward thrusting“ of Tarim basin is the main feature of crustal movement in this area.2)The rock layer in the upper crust of Tian-shan fold zone is relatively“soft“,which makes it prone to rupture and stress energy release.This is the primary tectonic factor for the concentration of small earthquakes in this area.3)Jiashi is located right over the apex or the inflection point of the updoming lower crustal interface C and the crust-mantle boundary,which is the deep struc-tural background for the occurrence of strong earthquakes.The alternate variation of vp/vs near the block bounda-ries and the complicated configuration of the interfaces in the upper and middle part of the upper crust form a par-ticular structural environment for the Jiashi strong earthquake swarm.vp/vs is comparatively high and shear modulus is low at the focal region,which may be the main reason for the low stress drop of the Jiashi strong earthquake swarm. 相似文献
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芦山与汶川地震之间存在约40 km的地震空区.震源区和地震空区的深部构造背景的研究对深入了解中强地震的深部孕育环境及地震空区的地震活动性具有重要科学意义.利用本小组布设的15个临时观测地震台以及21个芦山科考台站和21个四川省地震局固定台站记录的远震数据,用H-K叠加方法得到各个台站的地壳厚度和平均泊松比,并构建了接收函数共转换点(CCP)偏移叠加图像以及反演得到台站下方的S波速度模型.我们的结果揭示了震源区和地震空区地壳结构特征差异:(1)汶川震源区的地壳平均泊松比为~0.28;芦山震源区为~0.29;而地震空区处于泊松比变化剧烈的区域;(2)汶川地震与芦山地震的震源区以西下方的Moho面呈现深度上的突变(这与前人的研究成果基本一致),分别从~44 km突变到~59 km,~40 km突变到~50 km,而地震空区地壳平均厚度呈现渐变性变化;(3)地震空区Moho面下凹且具有低速的上地壳.综合一维S波速度结构和H-k以及CCP的初步结果,这可能显示汶川地震的发震断裂在深部方向上向西倾斜并形成切割整个地壳的大型断裂;芦山地震则可能是由于上、下地壳解耦引起的;而地震空区处于两种地震形成机制控制区域的过渡带中. 相似文献
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Crustal P-wave velocity structure in the northeastern margin of the Qinghai-Tibetan Plateau and insights into crustal deformation 总被引:1,自引:0,他引:1
Shuaijun Wang Baojin Liu Xiaofeng Tian Baofeng Liu Xianghui Song Xiaoguo Deng Yinan Sun Cejun Ma Yudong Yang 《中国科学:地球科学(英文版)》2018,61(9):1221-1237
The transitional area between the northeastern margin of the Qinghai-Tibetan Plateau, Ordos Block and Alxa Block,also being the northern segment of the North-South Seismic Belt, is characterized by considerably high seismicity level and high risk of strong earthquakes. In view of the special tectonic environment and deep tectonic setting in this area, this study used two seismic wide-angle reflection/refraction cross profiles for double constraining, so as to more reliably obtain the fine-scale velocity structure characteristics in both the shallow and deep crust of individual blocks and their boundaries in the study area,and further discuss the seismogenic environment in seismic zones with strong historical earthquakes. In this paper, the P-wave data from the two profiles are processed and interpreted, and two-dimensional crustal velocity structure models along the two profiles are constructed by travel time forward modeling. The results show that there are great differences in velocity structure,shape of intra-crustal interfaces and crustal thickness among different blocks sampled by the two seismic profiles. The crustal thickness along the Lanzhou-Huianbu-Yulin seismic sounding profile(L1) increases from ~43 km in the western margin of Ordos Block to ~56 km in the Qilian Block to the west. In the Ordos Block, the velocity contours vary gently, and the average velocity of the crust is about 6.30 km s-1; On the other hand, the velocity structures in the crust of the Qilian Block and the arclike tectonic zone vary dramatically, and the average crustal velocities in these areas are about 0.10 km s-1 lower than that of the Ordos Block. In addition, discontinuous low-velocity bodies(LVZ1 and LVZ2) are identified in the crust of the Qilian Block and the arc-like tectonic zone, the velocity of which is 0.10–0.20 km s-1 lower than that of the surroundings. The average crustal thickness of the Ordos Block is consistently estimated to be around 43 km along both Profile L2(Tongchuan-Huianbu-Alashan left banner seismic sounding profile) and Profile L1. In contrast to the gently varying intra-crustal interfaces and velocity contours in the Ordos Block along Profile L1, which is a typical structure characteristic of stable cratons, the crustal structure in the Ordos Block along Profile L2 exhibits rather complex variations. This indicates the presence of significant structural differences in the crust within the Ordos Block. The crustal structure of the Helan Mountain Qilian Block and the Yinchuan Basin is featured by "uplift and depression" undulations, showing the characteristics of localized compressional deformation.Moreover, there are low-velocity zones with alternative high and low velocities in the middle and lower crust beneath the Helan Mountain, where the velocity is about 0.15–0.25 km s-1 lower than that of the surrounding areas. The crustal thickness of the Alxa Block is about 49 km, and the velocity contours in the upper and middle-lower crust of the block vary significantly. The complex crustal velocity structure images along the two seismic sounding profiles L1 and L2 reveal considerable structural differences among different tectonic blocks, their coupling relationships and velocity structural features in the seismic zones where strong historical earthquakes occurred. The imaging result of this study provides fine-scale crustal structure information for further understanding the seismogenic environment and mechanism in the study area. 相似文献
17.
We obtain the preliminary result of crustal deformation velocity field for the Chinese con-tinent by analyzing GPS data from the Crustal Motion Observation Network of China (CMONOC), particularly the data from the regional networks of CMONOC observed in 1999 and 2001. We de-lineate 9 tectonically active blocks and 2 broadly distributed deformation zones out of a denseGPS velocity field, and derive block motion Euler poles for the blocks and their relative motionrates. Our result reveals that there are 3 categories of deformation patterns in the Chinese conti-nent. The first category, associated with the interior of the Tibetan Plateau and the Tianshan oro-genic belt, shows broadly distributed deformation within the regions. The third category, associatedwith the Tarim Basin and the region east of the north-south seismic belt of China, shows block-likemotion, with deformation accommodated along the block boundaries only. The second category, mainly associated with the borderland of the Tibetan Plateau, such as the Qaidam, Qilian, Xining(in eastern Qinghai), and the Diamond-shaped (in western Sichuan and Yunnan) blocks, has thedeformation pattern between the first and the third, i.e. these regions appear to deform block-like,but with smaller sizes and less strength for the blocks. Based on the analysis of the lithosphericstructures and the deformation patterns of the regions above, we come to the inference that thedeformation modes of the Chinese continental crust are mainly controlled by the crustal structure.The crust of the eastern China and the Tarim Basin is mechanically strong, and its deformationtakes the form of relative motion between rigid blocks. On the other hand, the northward indentation of the Indian plate into the Asia continent has created the uplift of the Tibetan Plateau and the Tianshan Mountains, thickened their crust, and raised the temperature in the crust. The lower crust thus has become ductile, evidenced in low seismic velocity and high electric conductivity observed. The brittle part of the crust, driven by the visco-plastic flow of the lower crust, deforms extensively at all scales. The regions of the second category located at the borderland of the Tibetan Plateau are at the transition zone between the regions of the first and the third categories in terms of the crustal structure. Driven by the lateral boundary forces, their deformation style is also between the two, in the form of block motion and deformation with smaller blocks and less internal strength. 相似文献