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1.
秦岭造山带作为典型的陆内复合造山带,发生过强烈的构造变形,与北部的渭河地堑形成独具特色的盆山构造体系,目前其深部结构状态与盆山耦合响应缺乏深层动力学过程的理解,为此以跨越秦岭造山带、渭河地堑布设一条170 km的大地电磁测深剖面,通过宽频带和长周期大地电磁观测,构建秦岭造山带和渭河地堑深部地电结构,研究结果表明:1)秦岭造山带存在多重叠置的巨厚岩石圈,南秦岭与北秦岭地壳尺度存在明显的结构化差异; 2)扬子地块向北楔入到南秦岭岩石圈地幔中,南、北秦岭之间在上地幔存在低阻条带痕迹表明了楔入作用的前缘位置; 3)渭河地堑存在巨厚的沉积盖层,厚度由南向北逐渐减薄,由南侧的7~8 km减到北侧的3~4 km。渭河地堑下地壳至上地幔区域分布的两个低阻块体表明其岩石圈存在明显的电性差异,这种差异性的存在表征了华北地块南向挤压作用背景下软流圈上涌的贡献。 相似文献
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青藏高原东北缘六盘山—鄂尔多斯盆地深地震测深剖面沿近东—西向布设长约420km,跨越鄂尔多斯盆地、六盘山和秦祁地块。本文根据沿测线爆破地震的6炮记录截面图中,6个震相的到时资料,结合地震记录中的振幅信息,确定了沿剖面的二维纵波地壳速度结构。鄂尔多斯盆地的地壳平均速度为6.38~6.40km/s,地壳厚度为41.7~48.2km。六盘山地区的地壳平均速度最高为6.40~6.42km/s,地壳厚度最大为53~54km。六盘山以西秦祁地块的地壳平均速度最低为6.32~6.40km/s,地壳厚度为50.3~53km。整个莫霍面形态东浅西深,明显向西倾斜。鄂尔多斯盆地东侧的莫霍面深度最浅为41.7km,六盘山下方莫霍面的深度最深为54km。莫霍面首波Pn在220km之后出现,速度为7.8~8.1km/s。最后讨论了本区的深部特征和盆山结构关系。 相似文献
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秦岭造山带前寒武纪地幔化学分区及壳幔物质循环——Pb,Nd同位素及微量元素证据 总被引:1,自引:1,他引:1
对秦岭造山带4个构造单元前寒武纪基性火山岩64个岩石样品的Pb同位素,24个岩石样品的Nd同位素和38个岩石样品的微量元素组成进行了同位素组成间、微量元素对比值间和同位素组成与微量元素含量比值间相关变异分析,并研究了岩石Pb同位素组成的拓扑学特征.结果表明:秦岭造山带前寒武纪地幔可划分成4个化学分区;4个分区中华北地台南缘区长期独立演化,具典型大陆岩石圈特征;另3个地幔分区间相关演化,且均不同程度地与大洋环境相联系,说明在岩石圈尺度上前寒武纪北秦岭与华北地台间的边界是秦岭地区最重要的地幔化学不均一界面;前寒武纪北秦岭带幔源岩浆与南秦岭带和扬子地台北缘区幔源岩浆的源区组成既有差异,晚期又有一定相似性,反映前寒武纪晚期南秦岭带和扬子地台岩石圈块体已向北秦岭带和华北地台俯冲,故南北秦岭间的分界既是秦岭造山带内的地幔化学不均一界面,又是秦岭造山带岩石圈构造界面;秦岭造山带各构造区带在造壳过程同时也存在地壳物质回返地幔的过程,由于岩石圈构造环境的差异,不同时期各构造区带参加壳幔物质循环的地壳组分有所不同 相似文献
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南北构造带北段位于青藏高原东北缘及其向北东方向扩展的区域,其岩石圈变形特征对于探讨青藏高原东北缘变形机制及其扩展范围具有非常关键的意义。地震波各向异性能很好地反映上地幔的变形特征。因此,本文对布设在南北构造带北段的流动地震台站记录的远震波形资料进行S波分裂研究,获得了研究区上地幔各向异性图像以及该区岩石圈地幔的变形特征信息。S波分裂研究结果表明,研究区地震波各向异性来自于上地幔,区内不同构造单元上地幔各向异性方向不尽相同。快波方向分布显示,青藏高原东北缘,鄂尔多斯西缘以及贺兰构造带北段的快波方向主要表现为NW-SE向,与前人在银川地堑和贺兰构造带中、北部得到的NW-SE向的上地幔各向异性方向一致,显示这些地区岩石圈地幔变形一致,该结果表明青藏高原东北缘向北东方向扩展的影响范围已到达贺兰构造带北段。阿拉善地块内部快波方向显示为NE-SW向,与阿拉善地块北部存在的北东向展布的晚古生代岩浆岩方向一致,表明该NE-SW向的快波方向可能代表地是“化石”各向异性,是晚古生代阿拉善地块受到古亚洲洋闭合作用的结果。此外,鄂尔多斯地块内也存在NE-SW向的各向异性方向,与区内中-晚侏罗世存在的NE-SW向逆冲推覆构造方向一致,因此该各向异性方向也代表了“化石”各向异性,是鄂尔多斯地块受到古特提斯构造域的块体碰撞、古太平洋板块北西向俯冲以及西伯利亚板块向南俯冲共同作用的结果。 相似文献
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秦岭造山带是华北板块和扬子板块南北两个大陆边缘长期演化的产物,各部分性质和时代不同,是一个复杂的构造混杂体。由于其所处位置的重要性,演化时间上的长期性、多旋回性,空间上的多样性、变异性,一直是地质和地球物理学研究的热点。为了沟通该区复杂的浅表地质现象与深部结构成像,获取更精细的上地壳结构成为厘定秦岭造山带不同块体之间接触关系,揭示其地球动力学演化过程的关键。本文对一条长450 km、南北向跨越鄂尔多斯地块南缘、渭河地堑、秦岭造山带、大巴山逆冲推覆带和四川盆地北缘的宽角反射与折射地震剖面采集的15个大炮数据进行了层析成像研究。本研究对690个初至走时拾取数据使用有限差分算法,采用变网格尺度及平滑参数的迭代策略,经20次迭代反演,走时均方根误差降至0.105 s,收敛良好。成像结果精细刻画了渭河地堑的低速沉积特征,系一个南深北浅的断陷盆地,最深处可达7 km,其发育主要受秦岭北缘断裂、乾县—富平断裂及渭河断裂控制。秦岭北缘断裂与安康—竹山断裂之间的秦岭造山带上地壳呈高速特征,横向变化剧烈,仅残余若干较浅的山间盆地。与南部四川盆地稳定沉积相比,大巴山逆冲推覆带下方沉积层速度结构不统一,反映了逆冲推覆作用的改造,但整体仍保留了3~6 km的沉积厚度。本文分析认为剖面中部的秦岭地区是古生代—早中生代南北板块汇聚的核心地带,之后造山带两翼的南、北陆缘分别于燕山期和新生代转入逆冲推覆和伸展两种迥异的构造环境,而现今研究区的上地壳构造格局是三次事件叠加的结果。 相似文献
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苏鲁大别造山带岩石圈三维P波速度结构特征 总被引:13,自引:1,他引:13
本文全面收集整理并解析了地学断面、地震测深、体波和面波层析成像资料,得到了苏鲁大别造山带及其邻区岩石圈1°×1°三维P波速度数据体。研究结果表明,苏鲁与大别造山带高压、超高压变质带的岩石圈速度结构具有上地壳明显高速且上凸;中地壳增厚;下地壳埋藏较深且下凹等相似的基本特征。苏鲁和大别超高压变质带下的莫霍面比其周围深2~4 km,深度分别达到32~33 km和34~38 km。在大别造山带,有地壳低速体从南向北俯冲到上地幔的迹象,可能显示了扬子地块地壳物质向华北地块俯冲,坠入上地幔的残留体。超高压变质带岩石圈底部的地幔,往往有明显高速层或高速体存在。苏鲁与大别地区的岩石圈速度结构不同特征及其成因在于苏鲁地区上地壳P波速度更高,但是,下地壳下凹没有大别地区明显,而且区域构造较为均一。这可能是受到郯庐断层左行平移的主控影响所致。郯庐断裂带的上、中地壳和上地幔表现为相对低速异常,郯庐断裂及其地下延伸部分将岩石圈地幔浅部低速层和深部高速层切为两段,其影响深达岩石圈底部约90 km处。 相似文献
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青海东部地壳速度结构特征研究 总被引:17,自引:1,他引:16
测区的爆破地震测深资料研究结果表明 :自南向北 ,莫霍面呈现为阶梯状展布。羌塘地块具有最厚的地壳 ,厚约 76km ,平均速度为 6.35km/s ,并以金沙江缝合带为界 ,将其同巴颜喀拉地块区别开来。金沙江断裂向北北东方向缓角度插入巴颜喀拉地块之下 ,其莫霍面在玉树以北至清水河一带发生明显的错动 ,地壳减薄至 68km ,平均速度亦减小到 6.30km/s。东昆仑隆起带作为测区一个东西向狭窄的构造块体 ,其下的莫霍面再次抬升。然而 ,在柴达木盆地或其东缘 ,地壳近乎透明 ,地壳厚度减小到 64km ,平均速度也减小为 6.2 6km/s。在祁连南缘 ,地壳厚度又有增大的迹象 ,在东昆仑与祁连相接壤的青海湖南缘断裂一带 ,莫霍面在其南北两侧有明显的落差 ,且南浅 ( 58km)北深 ( 62km) ,反映了祁连构造域同东昆仑构造域之间的深部构造差异特征。同时 ,以东昆仑隆起带为轴 ,南北两侧的速度结构存在着明显的差异 :南部地区的地壳中部 10~ 30km之间存在一个速度为 5.80~ 5.85km/s、厚约 12km的低速层 ;然而在北部地区的柴达木东缘 ,不仅没有低速层出现 ,而且下地壳的地震波速明显偏小。这种速度结构上的明显差异似乎指示着青藏高原的北部边界就是昆仑隆起带的北缘。 相似文献
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松潘地块若尔盖盆地与西秦岭造山带岩石圈尺度的构造关系——深地震反射剖面探测成果 总被引:17,自引:2,他引:17
若尔盖盆地和西秦岭造山带作为青藏高原东北缘典型的新生代盆山构造,其接合部位的岩石圈结构及其深部构造关系为青藏高原东北缘板块碰撞的深部过程等研究奠定基础。横过盆山结合部位的深地震反射剖面长约63km,记录时间30s(TWT),探测深度超过莫霍面深达岩石圈地幔。该剖面首次揭露出青藏高原东北缘的盆山结合部位地壳和上地幔盖层的结构,发现了若尔盖盆地和西秦岭造山带下地壳以北倾为主的强反射特征,这种北倾的反射特征提供了若尔盖盆地俯冲到西秦岭造山带之下,而西秦岭造山带逆冲推覆到若尔盖盆地之上的地震学证据,初步揭示出若尔盖盆地和西秦岭造山带在挤压构造体系下形成的岩石圈尺度的构造关系,近于平坦的Moho反射特征反映两者在造山后期又经历了强烈的伸展作用。 相似文献
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利用地震台阵观测资料研究大庆地区深部构造 总被引:1,自引:0,他引:1
利用绥芬河-满洲里地学断面上布设的流动地震台阵,并结合固定地震台记录到的2009年6月-2011年5月间的远震资料,通过有限频方法开展体波走时层析成像研究,获取研究区上地幔三维P波速度结构;采用瑞利面波双台相速度和背景噪声相速度层析成像方法,反演研究区的三维S波速度结构。应用两种方法最终得到大庆地区三维速度分布特征。结果显示:松辽盆地地壳厚度较薄,盆地周边的大、小兴安岭隆起区厚度变厚,松辽盆地地壳内部多存在低速异常,壳幔及上地幔与周边相比呈现高速异常,分析上地幔物质上升会造成局部高速异常结构。速度结构异常多是南北向或北北东向,可能与区域性断裂对上、中地壳影响有关。 相似文献
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由1876个远震三分量P波地震图组成的数据集,取自布置于鄂尔多斯-太行山一线的宽频带流动台站。通过阵列反
卷积方法,得到地下界面响应的接收函数,并通过共转换点偏移叠加得到地下结构的图像。图像显示,从鄂尔多斯至渤海
湾盆地地壳厚度总体上逐渐变薄,Moho面总体呈小角度向西倾斜。鄂尔多斯块体中部地壳最厚,达到52 km,向东到鄂尔多
斯边缘,地壳厚度减小至43 km。太行山至渤海湾盆地地壳厚度从45 km减小至37 km。山西地堑下方Moho面上隆,和两边的
Moho面相比,抬升8~10 km,且其Moho面的上隆和新生代地堑的凹陷呈镜像关系。 相似文献
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1.IntroductionTheManzhouli-SuifenheGeoscienceTransect(M-SGT)isinthenortheastChina,acrosstheprovincesofInnerMongoliaandHeilongiiang.Geologically,itissitllatedamongtheplatesofNorthChina,SiberiaandWesternPacific.ThewholeIengthoftheM-SGTisaboutl3Ookm,whichcrossesmanytectonicunits(Fig.l).ItisclearthatitstectonicsitUationisuniqueanditsgeologicstructUreiscomplex.Deepearthquakeshappenfrequentlya1ongthetransect.Therefore,itisarepresentativeprofileofnortheastChinaandtheNortheastAsia.TheM-S… 相似文献
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The crust-mantle transition zone (CMTZ) is an important site for mass and energy exchange between the lower crust and upper mantle. Several kinds of CMTZ exist beneath the continent of China, which show different seismic reflection characteristics and are composed of different rock associations. In this paper, we identify three types of CMTZ in the continent of China. (a) The CMTZ beneath the Tibet Plateau exhibits a grid-shaped seismic reflection characterized by random and reticular high and low seismic velocity lamellae. It is about 30 km thick, comprising both mafic granulites of lower crust and ultramafic rocks of upper mantle. Such lithological association and seismic velocity structure were inherited from the crustal overthrust and overlapping during the Cenozoic collision between the Indian and Euro-Asian continents; The corresponding crust movement is still very intense in this region. (b) The CMTZ underneath North China Block is usually composed of a thinner strong positive velocity gradient l 相似文献
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We study high-resolution three-dimensional P-wave velocity (Vp) tomography and anisotropic structure of the crust and uppermost mantle under the Helan–Liupan–Ordos western margin tectonic belt in North-Central China using 13,506 high-quality P-wave arrival times from 2666 local earthquakes recorded by 87 seismic stations during 1980–2008. Our results show that prominent low-velocity (low-V) anomalies exist widely in the lower crust beneath the study region and the low-V zones extend to the uppermost mantle in some local areas, suggesting that the lower crust contains higher-temperature materials and fluids. The major fault zones, especially the large boundary faults of major tectonic units, are located at the edge portion of the low-V anomalies or transition zones between the low-V and high-V anomalies in the upper crust, whereas low-V anomalies are revealed in the lower crust under most of the faults. Most of large historical earthquakes are located in the boundary zones where P-wave velocity changes drastically in a short distance. Beneath the source zones of most of the large historical earthquakes, prominent low-V anomalies are visible in the lower crust. Significant P-wave azimuthal anisotropy is revealed in the study region, and the pattern of anisotropy in the upper crust is consistent with the surface geologic features. In the lower crust and uppermost mantle, the predominant fast velocity direction (FVD) is NNE–SSW under the Yinchuan Graben and NWW–SEE or NW–SE beneath the Corridor transitional zone, Qilian Orogenic Belt and Western Qinling Orogenic Belt, and the FVD is NE–SW under the eastern Qilian Orogenic Belt. The anisotropy in the lower crust may be caused by the lattice-preferred orientation of minerals, which may reflect the lower-crustal ductile flow with varied directions. The present results shed new light on the seismotectonics and geodynamic processes of the Qinghai–Tibetan Plateau and its northeastern margin. 相似文献
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华北地块南部巨型陆内俯冲带与秦岭造山带岩石圈现今三维结构 总被引:44,自引:1,他引:44
豫西横穿秦岭造山带的反射地震为主的综合地球物理探测,发现秦岭现今北界存在华北地块南部自北向南向秦岭的巨型陆内俯冲带,深达Moho面以下,与之相伴而生,在中上地壳发育自南向北的逆冲推构造带,千公里东西向延伸,主要发生于晚白垩世100Ma±,成为秦岭与华北地区块间中新生代重要陆内构造,它是秦岭造山带岩石圈现今三维结构的基本要素和组成部分,秦岭造山带岩石圈现今结构具有流变学分层的“立交桥”三维结构框架模型。显然它们具有统一的动力学背景,是秦岭造山带现今处于印度-青藏、太平洋和欧亚板块的西伯利亚地块等三大构造动力学体系复合部位,导致其从深部地幔动力学的最新调整到上部地壳响应所发生的壳幔等圈层相互作用的综合产物,可能是大陆长期保存、演化的主要途径与形式之一,具有重要的大陆动力学意义,对中国大陆构造、灾害、环境研究也具重要意义。 相似文献
16.
Claus Prodehl 《Tectonophysics》1981,80(1-4):255-269
The crustal structure of the central European rift system has been investigated by seismic methods with varying success. Only a few investigations deal with the upper-mantle structure. Beneath the Rhinegraben the Moho is elevated, with a minimum depth of 25 km. Below the flanks it is a first-order discontinuity, while within the graben it is replaced by a transition zone with the strongest velocity gradient at 20–22 km depth. An anomalously high velocity of up to 8.6 km/s seems to exist within the underlying upper mantle at 40–50 km depth. A similar structure is also found beneath the Limagnegraben and the young volcanic zones within the Massif Central of France, but the velocity within the upper mantle at 40–50 km depth seems to be slightly lower. Here, the total crustal thickness reaches only 25 km. The crystalline crust becomes extremely thin beneath the southern Rhônegraben, where the sediments reach a thickness of about 10 km while the Moho is found at 24 km depth. The pronounced crustal thinning does not continue along the entire graben system. North of the Rhinegraben in particular the typical graben structure is interrupted by the Rhenohercynian zone with a “normal” West-European crust of 30 km thickness evident beneath the north-trending Hessische Senke. A single-ended profile again indicates a graben-like crustal structure west of the Leinegraben north of the Rhenohercynian zone. No details are available for the North German Plain where the central European rift system disappears beneath a sedimentary sequence of more than 10 km thickness. 相似文献
17.
Upper lithospheric seismic velocity structure across the Pripyat Trough and the Ukrainian Shield along the EUROBRIDGE'97 profile 总被引:1,自引:0,他引:1
H. Thybo T. Janik V. D. Omelchenko M. Grad R. G. Garetsky A. A. Belinsky G. I. Karatayev G. Zlotski M. E. Knudsen R. Sand J. Yliniemi T. Tiira U. Luosto K. Komminaho R. Giese A. Guterch C. -E. Lund O. M. Kharitonov T. Ilchenko D. V. Lysynchuk V. M. Skobelev J. J. Doody 《Tectonophysics》2003,371(1-4):41-79
We present new results on the structure resulting from Palaeoproterozoic terrane accretion and later formation of one of the aulacogens in the East European Platform. Seismic data has been acquired along the 530-km-long, N–S-striking EUROBRIDGE'97 traverse across Sarmatia, a major crustal segment of the East European Craton. The profile extends across the Ukrainian Shield from the Devonian Pripyat Trough, across the Palaeoproterozoic Volyn Block and the Korosten Pluton, into the Archaean Podolian Block. Seismic waves from chemical explosions at 18 shot points at approximately 30-km intervals were recorded in two deployments by 120 mobile three-component seismographs at 3–4 km nominal station spacing. The data has been interpreted by use of two-dimensional tomographic travel time inversion and ray trace modelling. The high data quality allows modelling of the P- and S-wave velocity structure along the profile. There are pronounced differences in seismic velocity structure of the crust and uppermost mantle between the three main tectonic provinces traversed by the profile: (i) the Pripyat Trough is a ca. 4-km-deep sedimentary basin, fully located in the Osnitsk–Mikashevichi Igneous Belt in the northern part of the profile. The velocity structure is typical for a Precambrian craton, but is underlain by a ca. 5-km-thick lowest crustal layer of high velocity. The development of the Pripyat Trough appears to have only affected the upper crust without noticeable thinning of the whole crust; this may be explained by a rheologically strong lithosphere at the time of formation of the trough. (ii) Very high seismic velocity and Vp/Vs ratio characterise the Volyn Block and Korosten Pluton to a depth of 15 km and probably also the lowest crust. The values are consistent with an intrusive body of mafic composition in the upper crust that formed from bimodal melts derived from the mantle and the lower crust. (iii) The Podolian Block is close to a typical cratonic velocity structure, although it is characterised by relatively low seismic velocity and Vp/Vs ratio. A pronounced SW-dipping mantle reflector from Moho to at least 70 km depth may represent the Proterozoic suture between Sarmatia and Volgo–Uralia, the structure from terrane accretion, or a later shear zone in the upper mantle. The sub-Moho P-wave seismic velocity is high everywhere along the profile, with the exception of the area above the dipping reflector. This velocity change further supports a plate tectonic origin of the dipping mantle reflector. The profile demonstrates that structure from Palaeoproterozoic plate tectonic processes are still identifiable in the lithosphere, even where younger metamorphic equilibration of the crust has taken place. 相似文献
18.
F. Hauser V. Raileanu W. Fielitz A. Bala C. Prodehl G. Polonic A. Schulze 《Tectonophysics》2001,340(3-4):233-256
The VRANCEA99 seismic refraction experiment is part of an international and multidisciplinary project to study the intermediate depth earthquakes of the Eastern Carpathians in Romania. As part of the seismic experiment, a 300-km-long refraction profile was recorded between the cities of Bacau and Bucharest, traversing the Vrancea epicentral region in NNE–SSW direction.
The results deduced using forward and inverse ray trace modelling indicate a multi-layered crust. The sedimentary succession comprises two to four seismic layers of variable thickness and with velocities ranging from 2.0 to 5.8 km/s. The seismic basement coincides with a velocity step up to 5.9 km/s. Velocities in the upper crystalline crust are 5.9–6.2 km/s. An intra-crustal discontinuity at 18–31 km divides the crust into an upper and a lower layer. Velocities within the lower crust are 6.7–7.0 km/s. Strong wide-angle PmP reflections indicate the existence of a first-order Moho at a depth of 30 km near the southern end of the line and 41 km near the centre. Constraints on upper mantle seismic velocities (7.9 km/s) are provided by Pn arrival times from two shot points only. Within the upper mantle a low velocity zone is interpreted. Travel times of a PLP reflection define the bottom of this low velocity layer at a depth of 55 km. The velocity beneath this interface must be at least 8.5 km/s.
Geologic interpretation of the seismic data suggests that the Neogene tectonic convergence of the Eastern Carpathians resulted in thin-skinned shortening of the sedimentary cover and in thick-skinned shortening in the crystalline crust. On the autochthonous cover of the Moesian platform several blocks can be recognised which are characterised by different lithological compositions. This could indicate a pre-structuring of the platform at Mesozoic and/or Palaeozoic times with a probable active involvement of the Intramoesian and the Capidava–Ovidiu faults. Especially the Intramoesian fault is clearly recognisable on the refraction line. No clear indications of the important Trotus fault in the north of the profile could be found. In the central part of the seismic line a thinned lower crust and the low velocity zone in the uppermost mantle point to the possibility of crustal delamination and partial melting in the upper mantle. 相似文献