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本文根据1975-1984年期间发生的多个小地震的P波初动方向数据,推断了青、甘、川、滇地区平均主应力轴的方向。结果表明,该地区压应力轴(P轴)和张应力轴(T轴)方向皆水平,但其方位由北到南呈现规则转动的趋势,即主压应力轴在北部青甘地区大致取NE-SW方向,到中部川西北地区转为近E-W方向,再到南部云南地区转为NNW-SSE或近N-S方向。形成应力轴方向这样特定分布图象的原因,可用印度板块向北对青藏高原的推挤和缅甸中源地震带地区下沉物质对云南地区的拖曳作用来解释。 相似文献
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(李鸿吉,秦建业)FocalmechanismandmodernstressfieldalongtheBurmeseArcanditsvicinity¥Hong-JiLIandKin-YipCHEN(InstituteofGeophysics,Sta... 相似文献
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Double-couple point-source parameters for 11 of the largest intraplate earthquakes in the northern Indian Ocean during the last 20 y were determined from a formal inversion of long-period P and SH waveforms. Nine of the events have centroid depths at least 17 km below the seafloor, well into the upper mantle; two have centroid depths as great as 39 km. Using the source mechanisms of these earthquakes, we distinguish two major intraplate tectonic provinces in the northern Indian Ocean. To the west of the Ninetyeast Ridge, in the southern Bay of Bengal, intraplate earthquakes have thrust-faulting mechanisms with P axes oriented N-S. The centroid depths of these earthquakes range from 27 to 39 km below the seafloor. Lithospheric shortening in this region is thus accomplished by thrust faulting in the strong core of the oceanic upper mantle, while other geophysical evidence suggests that shallow sedimentary and crustal layers apparently deform predominantly by folding. In the immediate vicinity of the Ninetyeast Ridge, earthquakes display strike-slip mechanisms with left-lateral motion on planes parallel to the ridge. This type of faulting occurs from at least 10°S to the northern end of the Ninetyeast Ridge near 10°N, where the ridge meets the Sunda Arc. Seismic activity diminishes to the east of the Ninetyeast Ridge, but is also characterized by strike-slip faulting. Despite these variations in deformational style, the inferred orientation of greatest compressive stress in the northern Indian Ocean displays a consistent long-wavelength pattern over a large portion of the Indian plate, varying smoothly from nearly N-S in the Bay of Bengal to NW-SE in the northeastern Indian Ocean. This plate-wide stress pattern and the high level of intraplate seismicity in the northern Indian Ocean are likely the results of substantial resistance, along the Himalayan continental collision zone, to the continued northward motion of the western portion of the Indian plate. Oceanic intraplate earthquakes in other regions, where the level of deviatoric stress associated with the long-wavelength part of the stress field is likely to be smaller, need not be comparably reliable indicators of the plate-wide stress field. 相似文献
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针对2015年4月25日尼泊尔Mw7.8地震的孕震特征,本文首先对覆盖尼泊尔及周边地区的5套GPS水平速度场结果进行了融合,得到了近似统一参考框架下的速度场结果;在此基础上通过对此次地震震源区及周边地区的速度场、应变率场、基线时间序列分析,识别了震前变形特征.GPS应变率场结果显示,喜马拉雅主边界断裂存在大范围挤压应变积累,震源区处于近南北向应变积累高值过渡区.跨喜马拉雅构造带的GPS基线时间序列结果表现为持续缩短现象,表明印度板块与欧亚板块之间的持续挤压变形特征,2012年以来的缩短增强现象反映了印度板块对青藏块体的推挤增强作用明显.距离震中较近的西藏南部GPS同震位移结果以南向运动为主且指向震中,反映了青藏高原存在逆冲应变释放现象.综合此次尼泊尔地震前变形和同震应变释放特征,认为此次地震的孕震区域和同震应变释放区域均较大,将会对青藏高原的地壳变形与强震孕育产生深远影响. 相似文献
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On the basis of the GPS data obtained from repeated measurements carried out in 2004 and 2007,the horizontal principal strain of the Chinese mainland is calculated,which shows that the direction of principal compressive strain axis of each subplate is basically consistent with the P-axis of focal mechanism solution and the principal compressive stress axis acquired by geological method.It indicates that the crustal tectonic stress field is relatively stable in regions in a long time.The principal compressive stress axes of Qinghai-Tibet and Xinjiang subplates in the western part of Chinese mainland direct to NS and NNE-SSW,which are controlled by the force from the col-lision of the Eurasia Plate and India Plate.The principal compressive strain axes of Heilongjiang and North China subplates in the eastern part direct to ENE-WSW,which shows that they are subject to the force from the collision and underthrust of the Eurasia Plate to the North America and Pacific plates.At the same time,they are also af-fected by the lateral force from Qinghai-Tibet and Xinjiang subplates.The principal compressive strain axis of South China plate is WNW-ESE,which reflects that it is affected by the force from the collision of Philippine Sea Plate and Eurasia Plate and it is also subject to the lateral force from Qinghai-Tibet subplate.It is apparent from the comparison between the principal compressive strain axes in the periods of 2004~2007 and 2001~2004 that the acting directions of principal compressive stress of subplates in both periods are basically consistent.However,there is certain difference between their directional concentrations of principal compressive stress axes.The sur-face strain rates of different tectonic units in both periods indicate that the events predominating by compressive variation decrease,while the events predominating by tensile change increase. 相似文献
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D. D. Singh 《Pure and Applied Geophysics》1997,150(1):53-73
—Rayleigh and Love waves generated by sixteen earthquakes which occurred in the Indian Ocean and were recorded at 13 WWSSN stations of Asia, Africa and Australia are used to determine the moment tensor solution of these earthquakes. A combination of thrust and strike-slip faulting is obtained for earthquakes occurring in the Bay of Bengal. Thrust, strike slip or normal faulting (or either of the combination) is obtained for earthquakes occurring in the Arabian Sea and the Indian Ocean. The resultant compressive and tensional stress directions are estimated from more than 300 centroid moment tensor (CMT) solution of earthquakes occurring in different parts of the Indian Ocean. The resultant compressive stress directions are changing from north-south to east-west and the resultant tensional stress directions from east-west to north-south in different parts of the Indian Ocean. The results infer the counterclockwise movement of the region (0°–33°S and 64°E–94°E), stretching from the Rodriguez triple junction to the intense deformation zone of the central Indian Ocean and the formation of a new subduction zone (island arc) beneath the intense deformation zone of the central Indian Ocean and another at the southern part of the central Indian basin. The compressive stress direction is along the ridge axis and the extensional stress manifests across the ridge axis. The north-south to northeast-south west compression and east-west to northwest-southeast extension in the Indian Ocean suggest the northward underthrusting of the Indian plate beneath the Eurasian plate and the subduction beneath the Sunda arc region in the eastern part. The focal depth of earthquakes is estimated to be shallow, varying from 4 to 20 km and increasing gradually in the age of the oceanic lithosphere with the focal depth of earthquakes in the Indian Ocean. 相似文献
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2015年4月25日,在尼泊尔中部发生了Mw7.8地震.本文利用ALOS-2和SENTINEL-1A宽幅数据获取了该地震大范围的同震形变场,并反演了该地震断层破裂的几何特征及运动机制,继而以此为约束资料反演地震强地面运动.InSAR结果显示本次地震造成了巨大的地表形变,LOS向最大抬升量达到1.3 m,最大下沉量达到0.7 m.震源机制反演得到的最优的滑动分布模型表明,断层的走向为291°,倾角为7.6°,倾滑主要分布在深度为12~18 km范围,主倾滑分布范围在长度上达到了140 km,该范围内的平均倾滑角为95°.本次地震最大倾滑量达到5.3 m,位于深度15 km处.累计释放地震矩达 6.5×1020N·m,约合矩震级Mw7.8.该地震发生在印度与欧亚板块俯冲逆冲界面之间,发震构造推断为主喜马拉雅逆冲断裂,属于典型的喜马拉雅型——低角度逆断层型强震.以该滑动分布模型参数为基础利用随机振动的有限断层模型进行尼泊尔地震的强地面运动模拟,结果显示最大地震烈度为Ⅸ度,烈度分布的范围及烈度等级与USGS模型结果对比具有很高的符合度. 相似文献
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A present-day tectonic stress map for eastern Asia region 总被引:15,自引:1,他引:15
许忠淮 《地震学报(英文版)》2001,14(5):524-533
Introduction Tectonically the eastern Asia refers to the region bounded by the following three active tec-tonic zones: in the east the western Pacific subduction zone, including Japan trench, Ryukyu trench and Philippine trench; in the southwest the Himalaya continental collision zone and the Burma-arc-Java-trench subduction zone; in the northwest the Tianshan-Baikal continental defor-mation zone (Figure 6). In the world the eastern Asia is one of the regions with the strongest pre-sent-da… 相似文献
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39473 Pn travel times are inverted to tomographically image both lateral variation and anisotropy of uppermost mantle velocities
beneath China continent. The result indicates that the overall average Pn velocity of uppermost mantle in the studied region
is 8.0 km/s and the regional velocity fluctuation varies from ?0.30 km/s to +0.35 km/s. Pn velocities higher than 8.2 km/s
are found in the regions surrounding Qingzang Plateau, such as Junggar Basin, Tarim Basin, Qaidam Basin and Sichun Basin.
Pn velocities slightly lower than the average are found in western Sichuan and Yunnan, Shanxi Graben and Bohai Bay region.
A Pn velocity as low as 7.8 km/s may exist in the region striding the boundary between Guangxi and Guangdong provinces. In
general, Pn velocity in tectonically stable region like cratonic platform tends to be high, while that in tectonically active
region tends to be low. The regions in compressive setting usually show higher Pn velocity, while extensional basins or grabens
generally display lower one. Anisotropy of Pn velocity is seen in some regions. In the southeastern region of Qingzang Plateau
the directions of fastest Pn velocity show a rotation pattern, which may be related to southeastward escape of the plateau
material due to the collision and compression of Indian Plate to Asia along Himalaya arc. Notable anisotropy also exists around
Bohai Bay region, likely indicating crustal extending and possible magma activity therein. 相似文献
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四川盆地荣县—威远—资中地区属于历史弱震区,然而2019年相继发生多次破坏性地震事件.本文基于四川区域地震台网宽频带地震仪记录波形资料,利用CAP (Cut and Paste)波形反演方法,获得了2016年以来发生在荣县—威远—资中地区的26个MS≥3.0地震的震源机制解、震源矩心深度和矩震级,对该区域发震构造几何结构与变形特征及构造应力场特征进行了初步分析.主要获得如下认识:(1)26个MS≥3.0地震的震源矩心深度在1.5~5 km之间,平均深度3.4 km,表明事件发生在上地壳浅部沉积层内;震源深度分布揭示发震断层面倾向SE、缓倾角.(2)26个地震的震源机制全部为逆冲型,表明发震构造整体为逆断层性质.节面优势方位NNE-NE,结合走向与倾角统计结果,本文推测发震构造可能为威远背斜南翼一系列倾向SE、走向NNE-NE的缓倾角盲冲断层.(3)P、T、B轴优势方位单一,表明研究区域处于相对简单的构造应力环境.区域应力场反演获得的最大主压应力轴σ1方位NW-SE,近水平,与目前已知的该区域构造应力场水平主压应力方向一致,反映区内构造活动主要受区域构造应力场控制;其明显有别于四川盆地南缘2019年6月17日长宁MS6.0地震余震区NE-SW向的最大主压应力轴方位也揭示出四川盆地构造应力场具有明显的分区特征.(4)26个地震整体的应变花表现为NW-SE向挤压白瓣形态,表明区内发震构造整体呈NW-SE向纯挤压变形模式,明显有别于2019年长宁MS6.0地震序列NE-SW向挤压兼具小量NW-SE向拉张分量的构造变形模式,进一步表明四川盆地构造变形模式也具有明显的分区特征. 相似文献
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Takao Eguchi 《Physics of the Earth and Planetary Interiors》1983,33(4):318-327
The overall pattern of the recent tectonic stress field in the eastern part of the Eurasian plate is inferred from the geological features of large transcurrent and reverse faults, graben structures and from focal mechanism solutions of shallow earthquakes. NE-SW striking trajectory lines, of maximum horizontal tectonic stress axis (σ Hmax), are estimated at the north of Tibet and mainland China, but its strike turns to easterly near the eastern margin of the Eurasian plate. This suggests that the main origin of the σ Hmax in East Eurasia is due to a compressive stress regime along, the Himalayan belt, Tibet and the Japan Trench (and also the Sakhalin and Nankai Trough). This tectonic stress field seems to provide some influence on the extensional tectonics in the Shansi region, Baikal, and also in the Okinawa Trough where the N-S opening has been confirmed. The systematic view of the tectonic stress field in East Eurasia, makes it possible to appreciate the fundamental background of a number of complicated intra-plate tectonics. 相似文献
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喜马拉雅构造带及其临近区域是印度板块与欧亚大陆板块挤压碰撞的前缘地带.本文利用GPS实测速度场与震源机制解数据分别计算了研究区域现今地壳岩石圈表面的GPS应变场及岩石圈内部的主应力分布,研究了印度板块持续挤压作用下板块边界带地壳岩石圈现今地壳形变的空间分布特征.结果显示,南北向的剧烈挤压变形与东西向的拉伸变形是现今青藏高原南缘地壳岩石圈的主要变形特征.其中南北向的地壳挤压变形主要集中在主前缘冲断带与雅鲁藏布江缝合带之间.东西方向上,南北走向的亚东—谷露断裂是区域地壳东西向伸展变形的重要分界断裂.75°E是研究区域地壳形变的另一条显著不连续边界,其西侧地壳主压应变强度低、方向弥散且最大主压应力方向一致性较差,而东侧地壳主压应变方向与主压应力方向以及地壳水平运动速度场方向均具有较好的一致性.布格重力异常的小波多尺度辨析结果显示该分界带与循喜马拉雅西构造结楔入欧亚大陆的印度板块密切相关. 相似文献
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本文利用美国国家地震信息中心(NEIC)提供的1973~2006年地震目录,哈佛大学提供的1978-2005年地震机制解资料,研究了帕米尔-兴都库什地区印度板块与欧亚板块的碰撞形态,分析了印度板块向北俯冲对地震活动及其区域应力场的影响。地震震源三维图象显示:欧亚板块与印度板块在帕米尔"结"附近碰撞强烈,地震活动明显增强,震源剖面显示"V"字型分布形态;在帕米尔"结"东侧,随着印度板块俯冲动力减弱,地震活动也明显减弱,印度板块向北俯冲的剖面形态逐渐消失,欧亚板块向东南俯冲的剖面形态越加清晰;印度板块向北俯冲具有由浅向深、由南向北反复迁移的特征,可能反映印度板块向北俯冲→断离、再俯冲→再断离的过程。由于印度板块与欧亚板块间的强烈碰撞挤压作用,帕米尔-兴都库什地区处于以近南北向的挤压构造应力状态,逆断层数量约占70%,正断层数量约占11%,走滑断层数量约占19%。P轴优势方位显示帕米尔-兴都库什地区主压应力近南北向,倾角近水平,呈现由南向北倾斜;T轴倾角较大,近垂直,整体接近俯冲带的倾向。帕米尔-兴都库什地区应力场特征表明,印度板块向北的主动推挤,是形成这一区域应力场的主动力,向南倾的欧亚板块处于一种被动的被挤压状态。 相似文献
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Mahesh N. Shrivastava C. D. Reddy Sanjay K. Prajapati 《Pure and Applied Geophysics》2013,170(4):515-527
The deviatoric stress field are computed from the inversion of Gravitational Potential Energy (GPE) for the Indo-Eurasian plate collision region including the Himalaya and the Tibet Plateau. The resulting stress pattern in combination with stress and strain rates obtained by inverting, respectively, the focal mechanism solution of large earthquakes and GPS derived plate motions are used to study the nature of the present-day deformations. A narrow belt bordering the Himalayan collision zone from the south is characterized by strong compressive stresses. The variations in stress pattern along this belt coincide with arc-normal ridges extending into the Himalaya and are able to explain arc-parallel segmentation of seismicity. Gravitational collapse seems to play an important role in the southeastern Tibet Plateau. Depth sensitivity of the seismic derived stresses and GPS derived surface strain rates coupled with evidence of arcuate shaped high electrical conductivity favour strong ductile flow around the Eastern Himalaya Syntaxis (EHS) at mid-crustal depth. The deflection of crustal flow indicted by the viscous resistance offered by the rigid Sichuan basin adds to the traction stresses to cause clockwise rotation of the block around EHS. 相似文献
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IntroductionTheEastChinaSea(ECS)regionisapartoftheoff-shorecontinentalshelfregionintheeasternpartofChina.AlthoughmiddleandstrongearthquakesoccurfrequentlytoitssoutheastintheregionofOkinawatroughandRyukyuislandarc,andevenmorefrequentlytoitssouthinTaiw... 相似文献
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Contemporary tectonics in the Tien Shan region 总被引:1,自引:0,他引:1
James Ni 《Earth and Planetary Science Letters》1978,41(3):347-354
New fault plane solutions of recent earthquakes, along with previously published fault plane solutions, field geologic data, and faults interpreted from LANDSAT imagery indicate thrust faulting in the Tien Shan region. For most of the fault plane solutions compressive stress axes are nearly horizontal and trending approximately north-south, perpendicular to the trend of the Tien Shan fold belts. Contemporary tectonics of the Tien Shan region can be interpreted as resulting from convergence of the Indian and Eurasian plates. 相似文献