华北地区主要断裂带上的库仑应力变化及地震活动性分析

doi:10.3969/j.issn.0253-4967.2019.03.008

摘要/Abstract

摘要： 华北地区活断层丰富、地震频发。由于所处地理位置具有特殊性，其频繁的地震活动备受关注。为此，文中根据弹性位错理论和分层岩石圈模型，计算了1820年以来华北地区中强地震（M_S ≥ 6.0）引起的同震及震后介质黏弹性松弛产生的库仑应力变化。计算结果显示，自1888年渤海湾地震发生后的24个地震中，共有19个落在了库仑应力变化的正值区域，触发率达79%；计算结果进一步表明，宁河-新乡地震带的滦县-乐亭断裂、潘庄西断裂、东明-成武断裂、郓城断裂、隆尧断裂，郯庐地震带的营口-潍坊断裂，首都圈地区夏垫断裂，黄庄-高丽营断裂带上的库仑应力变化增加，其地震危险性相对较高，仍需要进一步的深入研究。

关键词: 库仑应力变化, 介质黏弹性松弛, 地震危险性, 华北地区

Abstract: In recent years, the Coulomb stress change induced by large earthquakes has attracted extensive attention in seismology. Many scientists at home and abroad have made remarkable achievements in the research on it. It is well known that North China is densely populated and industrially developed. More importantly, the Chinese capital city, Beijing, lies in the hinterland of North China. At the same time, there are abundant active faults and earthquakes in North China. The capital Beijing is China's political, economic, cultural, and transportation center. It is the center of all social activities and economic activities in the country, and is also a region where population, wealth, and information are highly concentrated. With the integration of Beijing-Tianjin-Hebei and the construction of Xiong'an New District, the consequences of big earthquake in Beijing and surrounding areas are unimaginable. Due to its special geographical location, frequent seismic activities in North China capture much attention. From the physical principle, the occurrence of earthquakes releases the accumulated stress, but the stress does not completely disappear. Some of the stresses are transmitted and transferred to other areas, resulting in stress concentration in some areas, which in turn affects the occurrence of earthquakes in the area. This is the idea of stress triggering of earthquakes. According to this hypothesis, the enhancement of Coulomb stress corresponds to the additional loading of the fault and promotes the occurrence of earthquakes; conversely, the weakening of the Coulomb stress in the stress shadow zone corresponds to partial unloading of the fault, which will delay the occurrence of the earthquake. In order to study the future seismic activity of North China, this paper estimates risks of future strong earthquakes in the region. To this end, we calculate the coseismic Coulomb stress changes and postseismic viscoelastic relaxation stresses of the events with M_S ≥ 6.0 that occurred in the North China region since 1820, using elastic dislocation theory and hierarchical lithosphere model, respectively, in order to examine whether the cumulative Coulomb stress change can explain the spatiotemporal pattern of large earthquakes. Also we project the Coulomb stress change onto the specific active faults in North China and assign the present and future Coulomb stress change state to the faults to provide a dynamics reference for analyzing whether the areas will be hit by strong earthquakes in the future. The simulated results show that the effect caused by the effective friction coefficient changes is not significant on the spatial distribution of Coulomb stress changes induced by coseismic and postseismic viscoelastic relaxation effect of the medium of earthquakes in the North China region. Although the variation of the effective friction coefficient has an impact on the Coulomb stresses for some sections of faults, the general pattern of the spatial distribution of the Coulomb stress changes keeps unchanged. Consequently, 19 of the 24 earthquakes since the 1888 Bohai Bay earthquake have fallen in the positive region of Coulomb stress changes, with a triggering rate of 79%. In particular, considering the seismogeological data and the Coulomb stress calculation results, we assume that Luanxian-Yueting Fault, Panzhuangxi Fault, Dongming-Chengwu Fault, Yuncheng Fault, Longyao Fault of Ninghe-Xinxiang seismic belt, the Yingkou-Weifang Fault of Tanlu seismic belt, the Xiadian Fault, and the Huangzhuang-Gaoliying Fault in the Capital area have higher seismic risk and deserve in-depth study.

Key words: Coulomb stress change, viscoelastic relaxation, seismic risk, North China

中图分类号:

P315.2

张群伟, 朱守彪. 华北地区主要断裂带上的库仑应力变化及地震活动性分析[J]. 地震地质, 2019, 41(3): 649-669.

ZHANG Qun-wei, ZHU Shou-biao. THE COULOMB STRESS CHANGES AND SEISMICITY ON SOME MAJOR FAULTS IN NORTH CHINA[J]. SEISMOLOGY AND GEOLOGY, 2019, 41(3): 649-669.

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