SEISMOLOGY AND GEOLOGY ›› 2021, Vol. 43 ›› Issue (1): 249-261.DOI: 10.3969/j.issn.0253-4967.2021.01.015

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SLIP RATES AND SEISMIC MOMENT DEFICITS ON MAJOR FAULTS IN THE TIANSHAN REGION

ZHU Shuang1), LIANG Hong-bao1), WEI Wen-xin2), LI Jing-wei1)   

  1. 1)The First Monitoring and Application Center, China Earthquake Administration, Tianjin 300180, China;
    2)Institute of Earthquake Forecasting, China Earthquake Administration, Beijing 100036, China
  • Received:2020-03-06 Revised:2020-09-07 Online:2021-02-20 Published:2021-05-06

天山地震带主要活动断层现今的滑动速率及其地震矩亏损

朱爽1), 梁洪宝1), 魏文薪2), 李经纬1)   

  1. 1)中国地震局第一监测中心, 天津 300180;
    2)中国地震局地震预测研究所, 北京 100036
  • 作者简介:朱爽, 女, 1987年生, 2012年于武汉大学测绘学院(院所)获大地测量学与测量工程专业硕士学位, 工程师, 主要从事GPS数据分析及地壳形变分析, E-mail:Shzhu1026@163.com。
  • 基金资助:
    国家重点研发计划项目(2018YFC1503606); 中国大陆地震重点监视防御区任务和震情跟踪青年课题(2020010229)共同资助

Abstract: Late Cenozoic and modern tectonic deformation in mainland China is mainly characterized by active block movement, and the average slip rate of faults in the fault zone at the block boundary is an important indicator for quantitatively measuring the intensity of fault activity. The Tianshan Mountains, as the largest revival orogenic belt within Eurasia, with crustal movement basically manifesting as near north-south deformation and a large number of strong seismic surface ruptures, is one of the regions with strong tectonic movement and one of the key seismic hazard zones in China. Many experts have conducted relevant studies on the Tianshan region using GPS technology and have obtained some useful conclusions. These studies have not divided and analyzed the fault zone in detail, but only divided the Tianshan seismic zone into several major fault zones, such as the eastern and western sections of the northern Tianshan, and the eastern and western sections of the southern Tianshan. In order to analyze the activity characteristics of the major faults in the Tianshan region more clearly, this paper refines the major faults and selects 14 major active faults in combination with the distribution of active faults in China proposed by Xu Xi-wei et al. 18 blocks are divided into secondary blocks in Tianshan region, with the major active blocks in the Tianshan region taken as the boundary; The GNSS data of the surrounding areas of 1999—2015 in the Tianshan seismic zone are collected in this paper and used to calculate the velocity field results, and the block locking depth and the slip rate of major faults are calculated using the elastic block model to quantify the seismogenic capacity of major faults. Because the fault closure will produce obvious elastic deformation gradient around the fault, the greater the depth of fault closure is, the greater the influence will be. The fault locking depth can be constrained by the method of GPS data fitting of this model, and the influence of fault locking depth is verified by the method of GPS minimum residual RMS in this paper. According to the optimal locking depth obtained in this paper, the velocity field in Tianshan area is simulated and calculated. The residual mean value of the velocity field simulated by the elastic block model is small, and the average velocity error in the east-west direction is 1.57mm/a, the average velocity error in the north-south direction is 1.72mm/a. At the same time, the slip rate of major faults is obtained. The results show that: the horizontal shortening of the whole Tianshan region is significant, which is consistent with the tectonic background of the region, and the shortening value in the southern Tianshan region is higher than that in the northern Tianshan region; the shortening tensile rate is significantly larger than the slip rate, which shows that the fault zone at basin mountain junction in the Xinjiang Tianshan region is dominated by backwash activity; the extrusion rate in the western section of the southern Tianshan fault zone is in a high value state, reaching(-6.3±1.9)mm/a, which is higher than that in the eastern part of the southern Tianshan; the extrusion rate in the western part of the northern Tianshan is also higher than that in the eastern part. All the strong earthquakes of magnitude 8 and more than 80% of the strong earthquakes of magnitude 7 and above in China occurred in the boundary zones of active blocks according to the historical records, the motion characteristics of the boundary zone of active blocks play an important role in controlling the generation and occurrence of earthquakes, and the seismicity of faults may be quantitatively calculated by the loss of seismic moment. In this paper, we collected a list of strong earthquakes of magnitude 6 and above in the Tianshan area since 1900, estimated the seismic moment release of the main faults in the Tianshan seismic zone based on the above list, and compared it with the calculated seismic moment accumulation to obtain the seismic moment loss of the corresponding fault. Among them, the maximum release of seismic moment of the Beiluntai Fault reached 8.69×1019N·m; due to the release of several moderate and strong earthquakes, the seismic moment of middle of Bo-A Fault and Keping Fault have not reached the deficit state at present, the surplus is -1.85×1019N·m and -3.06×1019N·m, respectively; The smallest area of earthquake release is the northern Tianshan mountain front fault, which is only 0.11×1019N·m, because there was only one earthquake with a magnitude of 6 in 1907, and the earthquake accumulation reached 11.53×1019N·m, generating an earthquake deficit of 11.42×1019N·m, which could produce a magnitude of 7.3 earthquake. The results show that front margins of the northern Tianshan Fault, the Maidan Fault, the north section of Ertix Fault and the west of Kashihe Fault have a large seismic moment loss and have the potential to generate earthquakes of magnitude 7 and above, while Beiluntai Fault and the middle section of the Keping Fault show a surplus state, and there is no possibility of a strong earthquake in a certain period of time in the future.

Key words: elastic blocks, GPS, Tianshan region, slip rate seismic moment deficit

摘要: 文中收集了1999—2015年天山地震带及其周边地区的GNSS数据, 计算得到了速度场结果, 并利用弹性块体模型计算了研究区域内各块体的闭锁深度和主要断层的滑动速率。 研究结果表明: 南天山断裂带西段的迈丹断裂的缩短速率处于高值状态, 达(-6.3±1.9)mm/a, 高于南天山东段; 北天山断裂带西段的缩短速率同样高于东段。 利用主要断裂带的滑动速率计算出各地震带的地震矩积累变化及1900年以来的地震矩释放变化量, 以分析地震矩亏损分布, 结果显示北天山山前断裂、 迈丹断裂、 额尔齐斯断裂带北段和喀什河断裂西段存在较大的地震矩亏损, 具有孕育7级以上地震的潜能, 而北轮台断裂、 柯坪断裂带中段则呈现地震矩盈余状态, 在未来的一段时间内不具备发生强震的可能。

关键词: 弹性块体模型, GPS, 天山地区, 滑动速率, 地震矩亏损

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