SEISMOLOGY AND GEOLOGY ›› 2024, Vol. 46 ›› Issue (5): 1207-1225.DOI: 10.3969/j.issn.0253-4967.2024.05.012

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THE INFLUENCE OF SEISMIC SOURCE CHARACTERISTICS ON VELOCITY PULSE DISTRIBUTION IN SCENARIOS: A TEST IN HUYA FAULT

JI Zhi-wei1)(), LI Zong-chao2),*(), ZHANG Yan2), JU Chang-hui1)   

  1. 1) Institute of Earthquake Forecasting, China Earthquake Administration, Beijing 100036, China
    2) Institute of Geophysics, China Earthquake Administration, Beijing 100081, China
  • Received:2023-10-06 Revised:2024-01-30 Online:2024-10-20 Published:2024-11-22

情景地震震源特征对速度脉冲分布的影响——以虎牙断层为例

纪志伟1)(), 李宗超2),*(), 张琰2), 琚长辉1)   

  1. 1) 中国地震局地震预测研究所, 北京 100036
    2) 中国地震局地球物理研究所, 北京 100081
  • 通讯作者: 李宗超, 男, 1989年生, 博士, 副研究员, 主要从事强地震动预测及其不确定性因素研究, E-mail: lizongchaoigo@163.com
  • 作者简介:

    纪志伟, 男, 1995年生, 助理研究员, 主要从事地震动模拟研究, E-mail:

  • 基金资助:
    国家自然科学基金(42104053); 国家自然科学基金(41904091); 中国地震局地震预测研究所基本科研业务专项(CEAIEF20220209); 中国地震局地震预测研究所基本科研业务专项(CEAIEF20240215)

Abstract:

In August 1976, within a week, three earthquakes with a magnitude of 6.5 or higher occurred at the border of Songpan County and Pingwu County in Sichuan Province, China. The seismogenic structure of the three earthquakes is the Huya Fault. The Huya Fault is still a strong active fault, and there is still a possibility of major future earthquakes in the Songpan and Pingwu regions. Historical earthquake records only represent earthquakes that have occurred, and there is uncertainty in estimating earthquake motion using existing records, especially in near-fault areas without strong earthquake records. Estimating near-fault ground motion has become a research hotspot in the interdisciplinary field of seismology and engineering seismology in recent years. The research and methods differ from the design of earthquake motion methods for earthquake safety evaluation in engineering. They are developed by integrating earthquake source physics, seismic wave propagation theory, and engineering seismology. Based on the geological and geomorphological characteristics of the Songpan-Pingwu area in Sichuan Province and the process framework for constructing scenario earthquake models, we have developed three scenario earthquake source models with a magnitude of MW7.0. These models include rupture models and source mechanisms related to the Huya Fault. The seismic source parameters were referenced from existing statistical models. Utilizing the three-dimensional finite difference method, we can simulate the long-term ground motion of scenario earthquakes for its facile discretization and computational efficiency. We set virtual observation stations within the calculated area, enabling the acquisition of velocity wave fields and waveforms across diverse earthquake scenarios. Besides, the velocity pulse identification method is combined to identify the seismic motion of the virtual station to study the distribution characteristics of regional velocity pulses. We use the pulse recognition method to identify velocity pulses of earthquake motion(observed or simulated earthquake motion). It can be summarized as a continuous wavelet transform of two orthogonal components of earthquake motion to determine whether it is a pulse. When the pulse index PI>0, the original record is determined to be a pulse, and the larger the PI, the stronger the pulse characteristics of the original record. When the pulse index PI<0, the original record is deemed nonpulse. This method can obtain the pulse amplitude and pulse period. Finally, the obtained results will be fitted with the probability distribution curve of velocity pulses to explore the impact of rupture mode and source mechanism on the distribution of velocity pulses. The results of this article indicate that: 1)The rupture mode is significant to the distribution of regional velocity pulses. For strike-slip faults, the velocity pulses caused by unilateral rupture mode are mainly in the E-W direction, and the peak value of the pulses does not exceed 50cm/s. The range of pulse distribution and the peak intensity of strong vibrations generated on the surface are smaller than the bilateral rupture mode. Strong velocity pulses not only appear near the projection area of faults on the surface but also trigger velocity pulses at a distance from the epicenter due to the directional effect of rupture. 2)The shape of the velocity pulse probability distribution curve is similar to the simulated velocity pulse distribution characteristics, and there are significant differences in the distribution of seismic motions under different source mechanisms. The current velocity pulse probability distribution model only considers the rupture characteristics and the relative position relationship between stations and faults without considering the influence of source parameters such as rupture velocity. There are deviations in the fitting effect for different components, such as E-W and N-S. The speed pulse period identified by virtual stations varies from 1-7s. By adding structural measures to the building structure, the natural vibration period of the structure can be changed, thereby avoiding the potential hazards of pulse-type seismic motion. More actual observation data is needed to study the distribution of velocity pulse periods in the future. This article’s simulation results are consistent with the existing understanding of earthquake motion. However, our study employs a simplified crustal structure characterized by horizontal layers, temporarily ignoring the site condition in the simulation of long-period ground motion. We do not encapsulate the complexities introduced by the site conditions. Average shear wave velocity at 30m underground (VS30) is a factor that affects the number of pulse recognition. In addition, this article does not discuss the effects of rupture speed, the number of asperities, and the position of asperities. Therefore, we will conduct more in-depth research on these factors in our subsequent work. The research in this article calculates the scenario earthquake of the Huya Fault under rupture mode and focal mechanism. The research results can be used for seismic analysis of long-period structures, providing a reference for the construction of significant projects and seismic hazard analysis near the Huya Fault. This article referred to previous research when setting parameters for scenario earthquakes. However, due to the limitations of statistical models, the set scenario earthquakes cannot fully represent the Huya Fault situation and the region’s possible earthquake scenarios.

Key words: Scenario earthquake, finite difference method, Huya Fault, velocity pulse, distribution probability

摘要:

文中根据中国四川省平武—松潘地区的地质地貌特征和情景地震模型构建流程, 建立虎牙断层不同震源特征的情景地震, 并采用三维有限差分法进行计算。结合脉冲识别方法研究区域速度脉冲的分布特征, 与速度脉冲概率分布曲线进行拟合。结果表明: 1)强速度脉冲不仅会出现在断层在地表的投影区域附近, 也会由于破裂方向性效应在距震中较远处引发速度脉冲; 2)速度脉冲概率分布曲线的形状与模拟得到的速度脉冲分布特征相似, 但不同震源机制下的速度脉冲分布存在明显差异, 对于不同分量(如EW和NS), 拟合效果也存在偏差; 3)对于长周期结构, 可通过构造措施改变自振周期, 从而避开脉冲型地震动的主要周期范围。文中的研究成果能够用于长周期结构的抗震分析, 可为虎牙断裂附近区域重大工程的建设和地震危险性分析提供参考。

关键词: 情景地震:有限差分法, 虎牙断层, 速度脉冲, 分布概率