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41.
CHARACTERISTICS OF SATELLITE GRAVITY FIELD AND SEISMOGENIC MECHANISM IN THE LONGMENSHAN FAULT ZONE 下载免费PDF全文
Longmenshan fault zone is a famous orogenic belt and seismic zone in the southeastern Tibetan plateau of China. The Wenchuan MS8.0 earthquake on May 12, 2008 and the Ya'an MS7.0 earthquake on April 20, 2013 occurred in the central-southern part of Longmenshan fault zone. Because of its complex geological structures, frequent earthquakes and special geographical locations, it has attracted the attention of many scholars around the world. Satellite gravity field has advantages in studying gravity field and gravity anomaly changes before and after earthquake. It covers wide range, can be updated regularly, without difficulty in terms of geographical restrictions, and is not affected by environmental factors such as weather, terrain and traffic. Therefore, the use of high-precision Earth satellite gravity field data inversion and interpretation of seismic phenomena has become a hot topic in earth science research. In order to understand satellite gravity field characteristics of the Longmenshan earthquake zone in the southeastern Tibetan plateau and its seismogenic mechanism of earthquake disasters, the satellite gravity data was used to present the terrain information of the study area. Then, by solving the regional gravity anomaly of the Moho surface, the crustal thickness of the study area was inverted, and the GPS velocity field data was used to detect the crustal deformation rate and direction of the study area. Combining the tectonic setting of the Longmenshan fault zone and the existing deep seismic sounding results of the previous researchers, the dynamic characteristics of the gravity time-varying field after the earthquake in the Longmenshan earthquake zone was analyzed and the mechanism of the earthquake was explored. The results show that the eastward flow of deep materials in the eastern Tibetan plateau is strongly blocked at the Longmenshan fault zone. The continuous collision and extrusion process result in a "deep drop zone" in the Moho surface, and the long-term stress effect is conducive to the formation of thrust-nappe and strike-slip structures. The Longmenshan earthquake zone was in the large-scale gradient zone of gravity change before the earthquake, the deep plastic fluid material transport velocity differed greatly, the fluid pressure was enhanced, and the rock mechanical strength in the seismic source region was weakened, which contributed to the intrusion of crustal fluid and the upwelling of the asthenosphere. As a result, the continuous accumulation of material and energy eventually led to continuous stress imbalance in the deep part and shear rupture of the deep weak structure, causing the occurrence of the thrust-nappe and strike-slip earthquake. 相似文献
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In this study,data from the Xinjiang regional network and IRIS shared global stations are used to relocate the Akto M_S6. 7 earthquake sequence on November 25,2016 by using double difference location method. Three earthquakes of M_S4. 8,M_S6. 7 and M_S5. 0 are inverted by using the g CAP method,and the focal mechanism solutions are obtained.According to the results of relocating,the location of the main shock is 39. 22°N,73. 98°E,the distribution of the earthquake sequence is about 70 km in length,and the focal depth is mainly within the range of 5-20 km. The plane and depth profiles of the earthquake sequence show that aftershocks extended in SEE direction after the main shock and the dip angle of fault plane is steep. Focal mechanism results show that the three earthquakes are characterized by strike-slip movement. Based on the results of field geological investigation,it is inferred that the seismogenic fault of the Akto earthquake is Muji fault,which is located at the northernmost end of the Kongur extensional system.The possible cause of this earthquake is that the Indian Plate continues to push northward,and during this compression process,the Indian Plate is affected by the clockwise rotation of the Tarim basin,which causes the accumulation of right-lateral action of the Muji fault,resulting in this earthquake. 相似文献
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We monitored the amplitude changes of coda transmission waves around 500kHz across the frictional interface of a simulated 1.5-meter-long fault during normal stress holding test. We find that the amplitude of coda transmission waves increases with the logarithm of stationary contact time. Localized increase amounted to a level ranging from 4% to 16% along the fault is observed during the 1-hour experiment. We discuss that the frictional strength at mesoscopic scale, which is related to the amplitude of coda transmission waves, is responsible for the phenomenon. Combining the reported method with other complementary approaches will enhance the understanding of fault mechanism either at laboratory or on-site applications. 相似文献
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郯庐断裂带江苏段地区4个剖面进行了土壤气Rn体积活度和CO2浓度测量结果显示, 自北向南土壤气Rn体积活度均值分别为22.9 kBq/m3、 35.5 kBq/m3、 40.2 kBq/m3、 26.6 kBq/m3; 自北向南土壤气CO2浓度均值分别为0.669%、 0.400%、 0.503%、 1.109%。 土壤气Rn体积活度和CO2的浓度在空间分布上具有较好的一致性, 这可能与CO2是Rn的载气有关。 综合分析土壤气Rn和CO2测量结果以及水准资料可得, 2017年土壤气Rn高值出现在晓店段可能与区域应力应变调整有关。 本研究不仅为研究区以后的土壤气研究提供了参考, 同时也可为研究区的构造活动研究提供地球化学资料参考。 相似文献
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利用程海断裂带附近27个数字地震台站远震波形资料, 提取每一个台站的接收函数, 计算出各台站莫霍面深度同时利用时间域线性反演方法, 获得了各个台站下方的横波速度。 结果显示: 程海断裂带莫霍面深度从南部42 km增至北部的54 km, 南部和北部莫霍面深度有明显的不同。 从程海断裂带下方不同深度S波速度剖面可以看出, 宾川及其北东部地区中下地壳存在明显的低速层, 此低速层可能与还没有固结的热物质有关。 而永胜南部地区, 地壳中S波速度垂直变化剧烈, 低速异常高速异常交替丛生, 这可能是此区地震频发的主要原因。 同时, 本文对宽频带地震仪和短周期地震仪得到的接收函数进行了初步的对比分析。 相似文献
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为研究汤东断裂带土壤气体地球化学特征及其所反映的构造地球化学背景, 采用野外监测的方法分析了张河村与邢李庄村两条测线的土壤H2、 Rn分布特征。 结果表明, 张河村H2浓度、 Rn活度浓度的分布范围分别为0.24×10-6~174.7×10-6、 13.3~69.8 kBq·m-3, 背景值分别为14.26×10-6, 24.8 kBq·m-3。 邢李庄测线H2浓度、 Rn活度浓度的分布范围11.8×10-6~67.06×10-6、 43.6~72.6 kBq·m-3, 背景值分别为37.13×10-6、 72.6 kBq·m-3。 张河村测线在90~105 m处, H2、 Rn出现强烈高值异常, 而120~150 m处出现高值异常。 异常值位于断裂带附近, H2、 Rn气体测值对断裂位置具有良好的指示作用。 气体异常主要受汤东活动断裂构造控制, 汤东断裂下方的深大断裂和汤阴地堑中下地壳的低速体对深部气体释放有重要作用。 相似文献
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