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潜在震源区的划分主要包括潜在震源区范围的划定以及震级上限的确定,目前遵循地震构造类比和地震活动重复等原则。而活断层的分段特性也是潜在震源区划分时必须考虑的一个重要因素。大青山山前断裂带至今有3种不同的分段方案,文中比较分析了前人对大青山山前断裂带的分段,并在此基础上对大青山及山前盆地的潜在震源区作了新的划分。鄂尔多斯块体周缘被拉张性断陷盆地围绕,这些断裂系地震构造相似,且除呼包盆地外均有历史8级以上地震记录。文中将大青山山前断裂带与鄂尔多斯块体周缘断裂系进行了构造对比,特别是与华山山前断裂进行了断裂活动性定量对比,得出雪海沟到土左旗段的震级上限为8级,断裂两端潜源震级上限均为7.5级 相似文献
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依据民乐—张掖盆地及外围地区的断裂活动性对该盆地发生强震的危险地段和时间进行了预测.结果表明,盆地西缘的榆木山断裂西段和红崖堡断裂西段是发生强震的危险地段,在今后50年内发生6.5≤MS≤7.0地震的可能性较大 相似文献
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酒西盆地为河西走廊西段的一个压陷性盆地,其内发育了多条晚第四纪活动逆断裂、褶皱带,是未来具有发生破坏性地震的潜在震源区.通过对酒西盆地和邻近地区9个潜在震源区的长期地震活动水平的对比研究,发现不同震级档的潜在震源区基本处于各自的一个地震活动水平档上.据此将玉门潜在震源区地震活动水平与其它潜在震源区对比,并结合区内活动构造及历史地震等活动特征,判定其震级上限为MS7.0.指出地震活动水平对比方法可作为潜在震源区划分中的一个辅助手段. 相似文献
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《地震地质》2017,(6)
祁连山北缘冲断带位于祁连山北缘与走廊盆地群的交界处,其中民乐-大马营断裂位于冲断带的东段民乐盆地和武威盆地之中,是民乐盆地南缘断裂。东大河由北至南横穿民乐-大马营断裂东段。其上游的支流横穿断层,其中的斜河发育了形态完整的阶地(T1—T6),被断层错断并在各级阶地上形成了形迹明显的断层陡坎。各级阶地上的陡坎走向近EW,并且由老至新高度依次降低,反映了断层位移量的累积。为了获得陡坎的横剖面,利用无人机对被错断的阶地实施了0.52km2范围内的扫描,生成了高精度的数字高程模型(DEM)影像,并利用它提取了各级阶地的横剖面形态。根据Thompson等(2002)的模式对各级阶地的上、下盘面分别进行线性拟合,通过蒙特卡洛模拟得到T6—T3的位错量95%置信区间分别为13.26~15.67m、9.74~10.13m、5.86~7.35m和5.03~5.60m。为了得到河流阶地的年代数据,在各级阶地的河流相砾石层顶部进行14C采样,此位置的14C年龄代表了阶地离开水面的年龄。获得T6—T2的年龄(Cal BP)分别为(16 405±210)a、(11 197±45)a、(5 697.5±52.5)a、(4 470.5±54.5)a和(3 137.5±77.5)a。利用各级阶地上陡坎的位错量和年代数据,对民乐-大马营断裂的垂直滑动速率线性拟合的结果为(0.91±0.09)mm/a,是1条全新世活动断裂。为人口稠密的民乐和永昌地区地震危险性分析提供了重要的地震活动性参数。 相似文献
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潮汕盆地主要受控于北东向和北西向2组断裂构造,盆地及周缘曾发生过多次破坏性地震。因此,厘定相关断裂的构造特征和第四纪活动性,对合理评估区域地震危险性至关重要。在系统总结和分析已有第四系钻孔年代学的基础上,采用野外地质调查与地球物理勘探相结合的方法,对潮汕盆地及周缘断裂构造开展详细的研究工作。盆地周缘基岩区断裂构造野外解析表明,北西向断裂具有正断层性质,兼具左行走滑特征,北东向断裂以逆冲变形为主。结合盆地第四系覆盖区浅层人工地震探测和已有地层年代学分析结果,进一步厘定了榕江断裂、韩江断裂、饶平-汕头断裂和普宁-潮州断裂在潮汕盆地内的几何学展布和晚更新世以来的活动特征。 相似文献
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综合探查表明 ,福州盆地的主要断层均无全新世活动。通过区域地壳动力学与地震构造背景分析、地震活动水平统计对比等 ,综合判定了福州盆地的地震环境及主要断层潜在地震的最大震级。结果表明 :福州盆地位于台湾动力触角对大陆作用的弱影响区 ,但靠近强、弱影响区的过渡边界 ,处于有、无≥ 6级强震区的过渡地带。与福建—粤东北沿海发生过强震的地段相比 ,福州盆地及附近主要断裂的最晚活动时代偏老 ,壳内的低速层不显著。另外 ,在福建及邻区的 12个地震构造单元中 ,福州盆地单元的地震活动水平最低。该盆地西缘和南缘的闽候 -南屿断层和五虎山北麓断层是具有发生中等地震潜势的相对危险断层段 ,潜在地震的最大震级估值为MS6 .0和 5 .6 相似文献
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2013年4月20日发生在龙门山南段的芦山MS7.0地震是继发生在龙门山中北段的汶川MS8.0地震之后的又一次强震。本文通过震后地表变形特征、余震分布、震源机制解、石油地震勘探剖面、历史地震数据等资料,结合前人对龙门山南段主干断裂、褶皱构造特征的研究以及野外实地考察,应用活动褶皱及"褶皱地震"的相关理论,初步分析芦山地震的发震构造模式。认为芦山地震为典型的褶皱地震,发震断裂为前山或山前带一隐伏断裂。构造挤压产生的地壳缩短大部分被褶皱构造吸收。认为龙门山南段前缘地区具有活褶皱-逆断层的运动学特征,表明龙门山逆冲作用正向四川盆地内部扩展。 相似文献
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C. Sanz de Galdeano J. A. Peláez Montilla C. López Casado 《Pure and Applied Geophysics》2003,160(8):1537-1556
-- The main active faults of the Granada Basin are located in its central-eastern sector, where the most important tectonic activity is concentrated, uplifting its eastern part and sinking the western border. Several parameters related to the seismic potentiality of these active, or in some cases probably active, faults in this basin are used for the first time. Many of these faults can generate earthquakes with magnitudes larger than 6.0 MW, although this is not the general case. The fault situated to the N of Sierra Tejeda, probably the one responsible for the big earthquake of 25/12/1884, stands out, because it could generate an earthquake with magnitude 6.9 MW. Although at present all the data needed are not fully known, we consider that the final results show, as a whole, the average expected return periods of the faults in the Granada Basin. 相似文献
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2013年4月20日在龙门山南段发生M_W6.7强震,造成重大人员伤亡和财产损失.芦山地震发生后,针对发震断层是高角度还是低角度断层?断层的归属、性质和地震构造模型等问题,一直存在不同的认识和争议.本次研究采用了芦山震区的三条高精度二维人工地震反射剖面,结合区域地质、钻井资料,对芦山震区浅层沉积与构造变形进行综合解释;研究同时综合了震源机制解、小震重定位结果以及深地震探测剖面,并结合龙门山地区古生代以来的构造演化史,对震区地质构造进行解析.研究认为龙门山南段主要发育了三套不同层次的滑脱层并控制了上地壳形变,呈现多层滑脱、多期变形、构造叠加的复杂特征.2013年芦山地震的主要活动断层发育在深部约20 km滑脱层之上,倾向NW、倾角较陡大约在45°~50°,并产生反冲断层形成Y字状结构.地震地质解释表明,芦山地震的同震活动断层没有突破中生界和新生界,并非先前认为的双石—大川断裂(F4)或山前大邑隐伏断裂(F6);芦山地震的发震断层为一基底盲冲断层;深地震反射结果进一步揭示芦山地震的发震断层为一早期(古生代)形成的正断层.研究认为芦山地震发震构造符合简单剪切断层转折褶皱模型(Simple-shear Fault-Bend Fold),2013年芦山地震为一次非特征型地震.晚新生代以来在青藏高原向四川盆地强烈挤压持续作用下,早期正断层重新活动并产生了芦山地震.这种深部隐伏断层活化产生的特殊型地震,无疑增加了龙门山地区地震灾害的风险和不确定性. 相似文献
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A strong earthquake with magnitude MS6.2 hit Hutubi, Xinjiang at 13:15:03 on December 8th, 2016(Beijing Time). In order to better understand its mechanism, we performed centroid moment tensor inversion using the broadband waveform data recorded at stations from the Xinjiang regional seismic network by employing gCAP method. The best double couple solution of the MS6.2 mainshock on December 8th, 2016 estimated from local and near-regional waveforms is strike:271°, dip:64ånd rake:90° for nodal plane I, and strike:91°, dip:26ånd rake:90°for nodal plane Ⅱ; the centroid depth is about 21km and the moment magnitude(MW)is 5.9. ISO, CLVD and DC, the full moment tensor, of the earthquake accounted for 0.049%, 0.156% and 99.795%, respectively. The share of non-double couple component is merely 0.205%. This indicates that the earthquake is of double-couple fault mode, a typical tectonic earthquake featuring a thrust-type earthquake of squeezing property.The double difference(HypoDD)technique provided good opportunities for a comparative study of spatio-temporal properties and evolution of the aftershock sequences, and the earthquake relocation was done using HypoDD method. 486 aftershocks are relocated accurately and 327 events are obtained, whose residual of the RMS is 0.19, and the standard deviations along the direction of longitude, latitude and depth are 0.57km, 0.6km and 1.07km respectively. The result reveals that the aftershocks sequence is mainly distributed along the southern marginal fault of the Junggar Basin, extending about 35km to the NWW direction as a whole; the focal depths are above 20km for most of earthquakes, while the main shock and the biggest aftershock are deeper than others. The depth profile shows a relatively steep dip angle of the seismogenic fault plane, and the aftershocks dipping northward. Based on the spatial and temporal distribution features of the aftershocks, it is considered that the seismogenic fault plane may be the nodal plane I and the dip angle is about 271°. The structure of the Hutubi earthquake area is extremely complicated. The existing geological structure research results show that the combination zone between the northern Tianshan and the Junggar Basin presents typical intracontinental active tectonic features. There are numerous thrust fold structures, which are characterized by anticlines and reverse faults parallel to the mountains formed during the multi-stage Cenozoic period. The structural deformation shows the deformation characteristics of longitudinal zoning, lateral segmentation and vertical stratification. The ground geological survey and the tectonic interpretation of the seismic data show that the recoil faults are developed near the source area of the Hutubi earthquake, and the recoil faults related to the anticline are all blind thrust faults. The deep reflection seismic profile shows that there are several listric reverse faults dipping southward near the study area, corresponding to the active hidden reverse faults; At the leading edge of the nappe, there are complex fault and fold structures, which, in this area, are the compressional triangular zone, tilted structure and northward bedding backthrust formation. Integrating with geological survey and seismic deep soundings, the seismogenic fault of the MS6.2 earthquake is classified as a typical blind reverse fault with the opposite direction close to the southern marginal fault of the Junggar Basin, which is caused by the fact that the main fault is reversed by a strong push to the front during the process of thrust slip. Moreover, the Manas earthquake in 1906 also occurred near the southern marginal fault in Junggar, and the seismogenic mechanism was a blind fault. This suggests that there are some hidden thrust fault systems in the piedmont area of the northern Tianshan Mountains. These faults are controlled by active faults in the deep and contain multiple sets of active faults. 相似文献
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2008年5月12日四川省汶川县发生了MS8.0强烈地震.发震断层是龙门山断裂带的映秀—北川断裂.分析震前的GPS速度场发现,从巴颜喀拉块体西部到龙门山断裂带沿大约N103°E方向的缩短速率为13.0 mm/a,龙门山断裂带的右旋走滑速率1.1 mm/a,断裂带处于闭锁状态.四川盆地沿大约N103°E方向有少量的压缩变形,而沿SW方向有少量的拉张变形.同震位移场显示,这次地震可能是巴颜喀拉块体SE向逆冲与四川盆地NW向俯冲同时发生的.应变场分析发现,震前震中区的主压与主张应变率分别为-30.840×10-9/a与13.956×10-9/a,主压应变轴N105.4°E与震源机制解得到的主压应力轴的方向N103°E一致.由本文提出的应力-应变机制得到的断层滑动方向和走向与地表破裂调查和震源机制解得到的结果一致.印度、太平洋和菲律宾海板块与欧洲板块的相互作用是龙门山断裂带积累弹性应变能和孕育汶川地震的长期作用力.苏门达腊大地震使青藏高原和华南块体的相互作用加强,促进了汶川地震的发生. 相似文献