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1.
亚洲中部,沿天山的西端、阿尔泰山的西北端到贝加尔地区,是一条显著的NE向边界(天山—贝加尔边界),在它的两侧,地形、构造、地震活动和其他地球物理特征都有显著的差异。沿这条边界不存在同方向的大断层,同时,一系列NW向大型走滑断层与这条边界以大角度相交,这些断层的西北段在边界西北侧附近终止。总体上,这条边界西北侧是稳定的哈萨克斯坦地台和西伯利亚地台,东南侧主要是构造活动的天山、阿尔泰山及蒙古西部,因此,这条NE向构造边界是大陆内部的变形终止边界。中亚地区的陆块拼合过程在古生代末已结束,天山、阿尔泰山等造山带与北边的哈萨克斯坦地台和西伯利亚地台焊接为一体,经历中生代的固化。新生代以来,受印度-欧亚板块碰撞的影响,天山、阿尔泰山等造山带在NS向挤压力作用下发生变形,包括近东西向逆断层和NW向走滑断层的活动以及分散的地震。这些变形向北扩展时,被刚性、结构完整的哈萨克斯坦地台和西伯利亚地台截断终止,因而造成NE向天山—贝加尔边界。亚洲大陆内部块体的地壳强度和变形特征有明显的继承性,新生代以来,原来的地台(克拉通)继续保持结构完整和稳定性,几乎没有内部变形,而天山、阿尔泰山等古老的造山带则再次经历强烈变形。这不仅是由于印度板块继续向北推挤的影响,而且与这些地区自身的地壳和上地幔结构有关,同时NE向天山—贝加尔边界的西北侧哈萨克斯坦地台和西伯利亚地台对变形扩散的阻挡也起了重要作用。  相似文献   

2.
西太平洋边缘海盆地的扩张过程和动力学背景   总被引:34,自引:0,他引:34  
任建业  李思田 《地学前缘》2000,7(3):203-213
西太平洋集中发育了全球 75%的边缘海盆地 ,这些盆地形成于始新世、渐新世—中新世和晚中新世—第四纪 3个边缘海扩张幕。文中介绍了边缘海盆地的基本特征和发育模式 ,详细讨论了西北太平洋边缘海盆地周缘板块构造时空格架及其对边缘海盆地形成、演化和关闭过程的控制作用。太平洋板块的俯冲及俯冲带的后退 ,印度—亚洲大陆碰撞的远程效应以及澳洲与印度尼西亚的碰撞是边缘海盆地的 3个重要的区域性控制因素。印度—亚洲大陆的碰撞所形成的向东和东南的地幔流可能推动了东亚大陆东侧和南侧俯冲带的后退 ,并引发弧后扩张作用。同时 ,由这一碰撞引起的东亚大陆边缘NE或NNE向断裂的右旋走滑 ,进一步影响和控制了边缘海盆地的几何学特征及演化。澳大利亚和印度尼西亚的碰撞阻碍了俯冲带的后退 ,导致了南海、Sulu海和Celebes海盆地的扩张终止。同时这一碰撞推动菲律宾海板块向北运移 ,并使Bonin弧与中央日本碰撞 ,导致日本海关闭  相似文献   

3.
亚洲大陆逃逸构造与现今中国地震活动   总被引:26,自引:2,他引:24       下载免费PDF全文
嵇少丞  王茜  孙圣思  许志琴  李海兵 《地质学报》2008,82(12):1644-1667
2008年5月12日汶川地震让中国地学界强烈感受到深入研究地震地质与构造变形的重要性和肩负防震减灾巨大的社会责任。本文作者从构造地质学家的角度对中国大陆地震分布、成因规律以及发展趋势做了一些讨论。按地震分布,中国大陆可以粗分为两个区域,其交界是一条过渡带。该过渡带的东界是郯庐断裂及其和海南岛的连线,西界是齐齐哈尔—北京—邯郸—郑州—宜昌—贵阳—(越南)河内连成的线,后者其实就是松辽盆地的西界(大兴安岭的东界、太行山的东界、大娄山的东界)。我们不妨将上述两线所夹过渡带称之为“地震区分界线”。分界线以西的广大地区,活动断裂、活动褶皱、活动盆地都与印度板块楔入欧亚大陆造成的青藏高原隆升、快速侧向扩展、亚洲大陆逃逸构造活动有关。流变性较好的造山带(如青藏高原和天山)和流变性较差的古老地块(如塔里木、准噶尔、阿拉善、鄂尔多斯、四川盆地等)在其边界强烈对抗,形成强震。地震区分界线以东的中国沿海地区受太平洋和菲律宾海板块运动的影响也会发生地震,但其强度和频度与该线以西的青藏高原周边、天山、鄂尔多斯地块周缘以及张家口渤海断裂带上地震低得多。由太平洋板块在日本海沟向西深俯冲形成的地震在中国仅分布在吉林省珲春—汪清一带,这些深源地震对地面工程建筑破坏性不大。处于欧亚、菲律宾海和南海3个板块的交汇部位的我国台湾地震不断。受我国台湾地震的影响,闽粤沿海NW和NE向断裂往往被激活,形成地震。总之,虽然中国大陆的现代地震受太平洋、欧亚、印度和菲律宾海四大板块联合作用控制,但最主要、最直接、影响最大的还是印度板块楔入欧亚大陆造成的青藏高原隆升、快速侧向扩展和大陆逃逸。因此,对中国的地震研究不能仅局限于某区域或某条断裂,而应把整个亚洲大陆逃逸构造作为整体的、统一的“一盘棋”看待。  相似文献   

4.
台湾岛以南海域新近纪的弧—陆碰撞造山作用   总被引:11,自引:4,他引:11       下载免费PDF全文
台湾岛以南海域(台南滨海)弧—陆碰撞带位于欧亚板块、菲律宾海板块和南海的结合部位,是新近纪弧—陆碰撞研究的理想场所。本文通过对南海973航次在该区域的多道地震剖面的解释,认为台南滨海弧—陆碰撞带增生的火山—沉积楔由恒春海脊和高屏斜坡两部分组成,前者是菲律宾海板块的增生楔,后者是欧亚板块的增生楔,在增生楔体和火山弧之间是作为弧前盆地的北吕宋海槽。自中新世中期以来,南海洋壳开始沿着马尼拉海沟向菲律宾海板块俯冲,形成活动大陆边缘的增生部分——恒春海脊;与此同时菲律宾海板块开始向北西方向移动,前缘的吕宋岛弧距今6.5Ma以来朝着亚洲陆缘斜向汇聚,形成了被动大陆边缘的增生部分——高屏斜坡。由于菲律宾海板块和欧亚板块之间的斜向汇聚,弧—陆碰撞具有穿时性,造山作用首先发生在台湾岛的北部,然后向南部及台南滨海发展。  相似文献   

5.
文中根据北美大陆西南边缘造山带的构造地貌及新构造运动特征,建立了反S状大陆边缘造山带的三维构造力学模式,指出阿拉斯加地区为弧形右旋剪切隆升造山带;科迪勒拉造山带为直线右旋走滑造山带;马德雷山以南,延至加勒比海为一左旋沉降‘旋扭沟-弧-盆系统’。以此模式检验欧亚大陆南缘造山带,确定从阿尔卑斯经扎格罗斯、喜马拉雅至印度尼西亚蜿蜒曲折的山链是由四个反S状造山带连锁而成,导致它们的分解为四个构造体系的原因,与南半球冈瓦纳大陆裂解有关。依据上述的区域构造规律,作者认为青藏高原内部结构的原型为旋扭沟-弧-盆系统,属帕米尔—喀喇昆仑—喜马拉雅反S状造山带尾弧的组成部分。后经印度板块俯冲、青藏—三江—印度尼西亚反S状造山带头部弧右旋隆升两组动力系统叠加结果。  相似文献   

6.
俄罗斯贝加尔湖区伸展构造及与中国东部伸展构造对比   总被引:4,自引:0,他引:4  
在晚白垩世-始新世夷平面基础上,由于断裂作用形成了贝加尔裂谷系。断裂作用最大幅度超过10 km。在裂谷系中心部位发育的断层长度最大、最深、最早,并以准对称形式向四周扩展。贝加尔裂谷系是在地幔隆起和印度-欧亚大陆碰撞双重作用下形成。贝加尔裂谷系与中国东部新生代断陷盆地和汾渭裂谷系同时形成,并有密切的成因联系。它们的形成不仅受太平洋板块的俯冲和印度-欧亚大陆碰撞的制约和影响,而且位于中国西南部的地幔流发散中心,呈扇状向太平洋区流动,可能是它们在更深层次上的共同场源基础。  相似文献   

7.
强祖基  张立人 《地质论评》1983,29(5):448-448
中生代以来,中国东部地壳和岩石圈构造演化与西太平洋弧沟系有关。本文将提出中国东部地震活动性自北而西南有明显的差异,主要由于西太平洋弧沟系自北而南各段弧沟系消减类型不同及弧后具有不同的应力状态。喜山运动早、中期,太平洋—库拉板块活动脊消减到亚洲大陆东缘,弧后强烈扩张,发生  相似文献   

8.
陆陆碰撞过程是板块构造缺失的链条。印度板块与亚洲板块的碰撞造就了喜马拉雅造山带和青藏高原的主体。然而,人们对印度板块在大陆碰撞过程中的行为尚不了解。如大陆碰撞及其碰撞后的大陆俯冲是如何进行的、印度板块是俯冲在青藏高原之下还是回转至板块上部(喜马拉雅造山带内)以及两者比例如何,这些仍是亟待解决的问题。印度板块低角度沿喜马拉雅主逆冲断裂(MHT)俯冲在低喜马拉雅和高喜马拉雅之下已经被反射地震图像很好地揭示。然而,关于MHT如何向北延伸,前人的研究仅获得了分辨率较低的接收函数图像。因而,MHT和雅鲁藏布江缝合带之间印度板块的俯冲行为仍是一个谜。喜马拉雅造山楔增生机制,也就是印度地壳前缘的变形机制,反映出物质被临界锥形逆冲断层作用转移到板块上部,或是以韧性管道流的样式向南溢出。在本次研究中,我们给出在喜马拉雅造山带西部地区横过雅鲁藏布江缝合带的沿东经81.5°展布的高分辨率深地震反射剖面,精细揭示了地壳尺度结构构造。剖面显示,MHT以大约20°的倾斜角度延伸至大约60 km深度,接近埋深为70~75 km的Moho面。越过雅鲁藏布江缝合带运移到北面的印度地壳厚度已经不足15 km。深地震反射剖面还显示中地壳逆冲构造反射发育。我们认为,伴随着印度板块俯冲,地壳尺度的多重构造叠置作用使物质自MHT下部的板块向其上部板块转移,这一过程使印度地壳厚度减薄了,同时加厚了喜马拉雅地壳。  相似文献   

9.
帕米尔—西昆仑前陆褶皱带位于塔里木盆地西南缘 ,处于帕米尔—西昆仑、天山、塔里木盆地的交接地带 ,是新生代印度板块与欧亚大陆碰撞的结果 ,该地区为晚新生代陆内构造变形最强烈的地区之一。由于缺少地震测线、钻井、测井等深部资料 ,对于帕米尔—西昆仑前陆褶皱带的研究大多局限于地表变形 ,对其深层构造变形研究得较少。2 0 0 0年以来 ,塔里木油田分公司在帕米尔—西昆仑山北麓的乌泊尔、苏盖特、甫沙地区采集和重新处理了大批二维地震测线。笔者在上述地区分别选择品质较好的地震测线 ,综合深层和地表资料 ,建立 3条横穿帕米尔—西昆…  相似文献   

10.
再论岩石圈地幔蘑菇云构造及其深部成因   总被引:7,自引:12,他引:7       下载免费PDF全文
袁学诚 《中国地质》2007,34(5):737-758
根据地球物理资料的分析得到,除了东北吉辽地区太平洋板块向大陆俯冲外,当今中国东部其他地区大陆下都没有俯冲太平洋板块的证据。中生代以来中国东部发生的岩石圈巨变不是太平洋板块向中国大陆的俯冲所造成,而是由于软流圈物质上涌形成蘑菇云构造对岩石圈地幔的改造而引发的重大地质事件。软流圈物质的上涌使岩石圈地幔成为新生地幔与残剩地幔并存的结构,岩石圈被激活,稳定的克拉通地壳褶皱变形,地壳减薄,地震频发,岩浆活动活跃,地面沉降,并形成广袤的西太平洋边缘海。但是岩石圈厚度并未减薄,只是由于岩石圈地幔形成了蘑菇云结构使它的速度降低,与周遍地区的岩石圈结构产生明显差别。蘑菇云地幔发育的地区覆盖整个东南亚西太平洋地区。包括中国东北的中东部、华北的东部、华南的东南缘、马来半岛、印尼、菲律宾、日本海、黄海、东海、南海,加罗林盆地和菲律宾海盆。与这个东南亚西太平洋低速岩石圈地幔相对应,还存在一个巨大的大地椭球面正异常,它应是核幔边界的质量过剩所引起。它与印度洋—西藏地区核幔边界质量亏损引起的负大地椭球面异常孪生,并形成一个控制中国大陆构造的深层动力系统,这个动力系统产生的时代可能为中生代或晚古生代。它们之间的地幔环流造成了东南亚西太平洋岩石圈巨变,并驱动印度板块的北移和青藏高原的隆升。  相似文献   

11.
《Gondwana Research》2014,25(3-4):946-957
In addition to crustal thickening, distinctly different mechanisms have been suggested to accommodate the huge convergences caused by the continental collision between India and Eurasia. As the transition zone between the two grand tectonic domains of Asia, the Tethys and the Pacific, east Tibet and its surrounding regions are the ideal places to study continental deformation. Pervasive rock deformation may produce anisotropy on the scale of seismic wavelengths; thus, seismic anisotropy provides insight into the deformation of the crust and mantle beneath tectonically active domains. In this study, we calculated receiver function pairs of radial- and transverse-components at 98 stations located in Sichuan and Yunnan provinces, China. We selected 7423 pairs with high signal-to-noise ratio (SNR) and unambiguous Moho converted Ps phases (Pms) to measure the Pms splitting owing to the crustal anisotropy. Both the crustal thickness and the average crustal Vp/Vs ratio were calculated simultaneously by the Hk stacking method. The geodynamic implications were also investigated in relation to surface geological features, GPS velocities, absolute plate motion (APM), SKS/SKKS splitting, and other seismological observations. In addition to the fast polarization directions (FPDs) of the crustal anisotropy, we observed a conspicuous sharper clockwise rotation around the eastern Himalayan syntaxis than was revealed by GPS velocities. The distributed FPDs within and near the main active fault zones also favored the directions parallel to the faults. This implied that the deformation of a continuous medium revealed by GPS motions is a proxy for the deformation of the brittle shallow crust only, while the main active faults and the deep crustal interiors both play important roles in the deep deformation. Our results suggest that the deformation between the crust and upper mantle within the northernmost section of the Indochina block is decoupled due to the large difference in the directions between the observations related to the crust (GPS and crustal anisotropy) and mantle (APM and mantle anisotropy). Focusing on the transition zone between the plateau and the South China and Indochina blocks, we suggest that the motion of the Central Yunnan sub-block is a southeastward extrusion by way of tectonic escape. There is less deformation in the deep crust and the motion is controlled by the active boundary faults of the Ailaoshan–Red River shear zone to the west and the Xianshuihe–Xiaojiang fault to the east; the lower crustal flow within the plateau southeastward reached the Lijiang–Xiaojinhe fault, but further south it was obstructed by the Central Yunnan sub-block.  相似文献   

12.
青藏高原东部及周边现时地壳运动   总被引:8,自引:2,他引:6       下载免费PDF全文
通过1991—2001年期间在青藏高原东部及周边地区的GPS测量,获得该地区不同参考框架下的地壳运动速度场,其测量的速度精度高于2mm/yr。印度板块与华北地块之间的地壳形变分为喜马拉雅及高原南部、高原中部(拉萨—格尔木)和高原北部(格尔木—金塔)三部分,它们分别吸收了印度板块与欧亚板块汇聚速率的43%、24%和32%。在欧亚框架下和相对于成都,印度板块和华南地块之间存在着以东喜马拉雅构造结为轴心的顺时针巨型涡旋构造——滇藏涡旋构造,运动速度分别为26~6mm/yr和24~7mm/yr,总体上从北东方向转变为南东和南西方向,有别于青藏高原中部的北东方向。滇藏涡旋和东喜马拉雅构造结的形成与南迦巴瓦—阿萨姆“犄角”的楔入作用有关。  相似文献   

13.
东亚地区现代地壳运动特征与构造变形   总被引:4,自引:1,他引:4  
任金卫  马宗晋 《地学前缘》2003,10(Z1):58-65
根据“中国地壳运动观测网络”首次发布的GPS观测结果以及国际地球自转服务中心在 2 0 0 0年发布的ITRF97下的站速度矢量和“东南亚地球动力学项目”GPS网的观测结果 ,讨论了东亚地区现今地壳运动和构造变形特征。在ITRF97参考系下 ,中国大陆东部现今地壳运动以向南东方向(12 0 130°)运动为主 ,量值平均为 35mm/a ,西部受印度板块向北东碰撞的影响 ,运动方向发生偏转 ,呈显北东—近东西向运动 ,但这种影响涉及的范围达到了准噶尔盆地北缘一线 ,说明碰撞型板块边界对板内变形的影响远大于俯冲型板块边界。平均来看 ,75 %以上的印度板块相对于欧亚板块间的南北向缩短是通过地壳增厚变形来吸收的 ,这意味着在调节整个青藏高原构造变形的过程中 ,逆断和地壳增厚起了主要的作用。东南亚块体总体上与欧亚板块的运动有所差异 ,相对于欧亚大陆有 10mm/a左右向东的运动。菲律宾板块南部向西的运动速度只有 2 4mm/a。包括华南地块在内的东南亚块体的运动不仅仅是与印度板块的碰撞过程有关 ,也应当与沿着东南亚块体东边界的俯冲过程有关。  相似文献   

14.
Northward indentation of the Indian Plate has brought about significant tectonic deformation into East Asia. A record of long-term tectonic deformation in this area for the past 50 M yr, particularly the vertical axis rotation, is available through paleomagnetic data. In order to depict rotational deformation in this area with respect to Eurasia, we compiled reliable paleomagnetic data sets from 79 localities distributed around eastern Himalayan syntaxis in East Asia. This record delineates that a zone affected by clockwise rotational deformation extends from the southern tip of the Chuan Dian Fragment to as far as the northwestern part of the Indochina Peninsula. A limited zone that experienced a significant amount of clockwise rotation after an initial India–Asia collision is now located at 23.5°N, 101°E, far away from an area (27.5°N, 95.5°E) where an intense rotational motion has been viewed by a snapshot of GPS measurements. This discrepancy in clockwise rotated positions is attributed to southeastward extrusion of the tectonic blocks within East Asia as a result of ongoing indentation of the Indian Plate. A quantitative comparison between the GPS and paleomagnetically determined clockwise rotation further suggests that following an initial India–Asia collision the crust at 30°N, 94°E paleoposition was subjected to southeastward displacement together with clockwise rotation, which eventually reached to present-day position of 23.5°N, 101°E, implying a crustal displacement of about 1000 km during the past 50 M yr.  相似文献   

15.
The eastern Himalayan syntaxis in Namjagbarwa is a high-grade metamorphic terrain formed by the India-Eurasia collision and northward indentation of the Indian continent into Asia. Right- and left-lateral slip zones were formed by the indentation on the eastern and western boundaries of the syntaxis respectively. The Dongjug-Mainling fault zone is the main shear zone on the western boundary. This fault zone is a left-lateral slip belt with a large component of thrusting. The kinematics of the fault is consistent with the shortening within the syntaxis, and the slipping history along it represents the indenting process of the syntaxis. The Ar-Ar chronological study shows that the age of the early deformation in the Dongjug-Mainling fault zone ranges from 62 to 59 Ma. This evidences that the India-Eurasia collision occurred in the early Paleocene in the eastern Himalayan syntaxis.  相似文献   

16.
We conducted a comprehensive 40Ar/39Ar geochronological study of the Jiali and Gaoligong shear zones to obtain a better understanding of crustal deformation and tectonic evolution around the Eastern Himalayan Syntaxis (EHS). The new age data reveal that the main phase of deformation in the Jiali and Gaoligong shear zones occurred from 22 to 11 Ma and from 18 to 13 Ma, respectively. Structural data collected during this study indicate that the Jiali shear zone underwent a change in shear sense from sinistral to dextral during its movement history. Based on a comparison with the deformation histories of other major shear zones in the region, we argue that the initial sinistral motion recorded by the Jiali shear zone was coincident with that of the Ailao Shan–Red River shear zone, which marked the northern boundary of the southeastward extrusion of the Indochina block during the Early Miocene. From the Middle Miocene (~18 Ma), the Jiali shear zone changed to dextral displacement, becoming linked with the dextral Gaoligong shear zone that developed as a consequence of continued northward indentation of the Indian continent into Asia. Since this time, the Jiali and Gaoligong shear zones have been united, defining the southwestern boundary of the EHS during clockwise rotation of the eastward-extruding Tibetan block, as revealed by recent GPS data. The temporal change in regional deformation pattern from southeastward block extrusion to clockwise rotation of crustal fragments may have played an important role in the development of the eastern Himalayan drainage system around the EHS.  相似文献   

17.
青藏高原东缘旋转变形机制的数值模拟   总被引:1,自引:0,他引:1  
在印度板块与欧亚板块的碰撞作用下,青藏高原受到华南块体、鄂尔多斯块体等不同程度的阻挡,引起高原的整体隆升。青藏高原东南缘发生物质向南"逃逸",青藏高原东缘现今的地壳运动表现为围绕青藏高原东构造结发生顺时针的旋转。针对青藏高原东缘的旋转变形特征,基于以大型活动断裂为界的块体构造模型,利用粘弹性接触单元有限元模拟,分析了控制青藏高原东缘旋转变形的动力学环境,模拟的GPS速度与实测GPS速度能够较好的地吻合,构造应力场分布特征和活动断层的性质也能够较大程度地吻合,模拟过程采用的边界及其代表的动力学环境表明,青藏高原东缘整体受控于印度板块的持续碰撞和稳定的华南板块的阻挡,在下地壳的拖曳和重力作用下,青藏高原物质从南部边界"逃逸"。在"逃逸"过程中,受印度板块斜向俯冲作用的影响,沿实皆断裂缅甸板块对巽他板块的剪切拉升作用是形成围绕喜马拉雅东构造结的旋转运动和地壳变形的重要因素,也是青藏高原东南缘旋转活动构造体系的主要影响因素之一。  相似文献   

18.
The eastern Himalayan syntaxis in southeastern Tibet consists of the Lhasa terrane, High Himalayan rocks and Indus‐Tsangpo suture zone. The Lhasa terrane constitutes the hangingwall of a subduction zone, whereas the High Himalayan rocks represent the subducted Indian continent. Our petrological and geochronological data reveal that the Lhasa terrane has undergone two stages of medium‐P metamorphism: an early granulite facies event at c. 90 Ma and a late amphibolite facies event at 36–33 Ma. However, the High Himalayan rocks experienced only a single high‐P granulite facies metamorphic event at 37–32 Ma. It is inferred that the Late Cretaceous (c. 90 Ma) medium‐P metamorphism of the southern Lhasa terrane resulted from a northward subduction of the Neo‐Tethyan ocean, and that the Oligocene (37–32 Ma) high‐P (1.8–1.4 GPa) rocks of the High Himalayan and coeval medium‐P (0.8–1.1 GPa) rocks of the Lhasa terrane represent paired metamorphic belts that resulted from the northward subduction of the Indian continent beneath Asia. Our results provide robust constraints on the Mesozoic and Cenozoic tectonic evolution of south Tibet.  相似文献   

19.
The collision between India plate and Eurasia continent 55 Ma ago caused the convergence between Southwest Tienshan and Pamirs tectonic systems, and conclusions by other researchers also suggest that the convergence will continue. Studies on the collision between these systems are helpful to the knowledge of the history and the tendency of the in-land tectonics since Cenozoic and are important in science and the real world as for environment changes, resources and energy reform, and forecast of earthquakes. For this reason, by means of digital modeling, on the basis of crustal shortening rate, crustal motion rate and data of physical properties of rocks, with the help of the FE (finite element) theory-based marc software, the United States, we address on the tendency of the convergence in this area in almost 10 Ma and draw a conclusion that the converged borders move northward and stretch southeast. The Southwest Tienshan will move more slowly and suffer less deformation than the Pamirs-West Kunlun (昆仑) system. The Pamirs-West Kunlun system will rotate counterclockwise while moving northward and extending westward.  相似文献   

20.
中国大陆现今构造运动的GPS速度场与活动地块   总被引:141,自引:11,他引:130  
张培震  王琪  马宗晋 《地学前缘》2002,9(2):430-441
GPS观测结果给出了在欧亚参考框架下周边板块的运动状态 ,印度板块的运动方向约NE2 0° ,速度是 40~ 42mm/a ;北美板块的运动方向约NW 2 80°~ 2 90° ,速度是 2 1~ 2 3mm/a ;菲律宾板块的运动方向是NW 2 90°~ 310° ,速度是 37~ 45mm/a ;哈萨克—西伯利亚地盾的运动方向约NE130° ,速度是 3~ 5mm/a。GPS所揭示的中国大陆现今运动场清晰地表现出了以活动地块为单元的分块运动特征。文中给出了各主要活动地块的运动方向和速度。大部分活动地块内部结构完整 ,以整体性的运动为主 ;个别活动地块内部发生构造变形 ,地块的整体性不好。中国大陆以活动地块为单元的现今构造变形可能与大陆岩石圈的结构和性质有关 ,上地壳以脆性变形为主 ,下地壳和上地幔以粘塑性的流变为特征 ,从底部驱动着上覆脆性地块的整体运动。  相似文献   

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