Three-dimensional numerical modeling of ground motion in the Valley of Mexico: A case study from the Mw3.2 earthquake of July 17, 2019

IF 3.1 2区 工程技术 Q2 ENGINEERING, CIVIL Earthquake Spectra Pub Date : 2023-09-16 DOI:10.1177/87552930231192463
Victor Moises Hernández-Aguirre, Roberto Paolucci, Francisco José Sánchez-Sesma, Ilario Mazzieri
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Abstract

In this study, a 3D physics-based numerical approach, based on the spectral element numerical code SPEED, is used to simulate seismic wave propagation due to a local earthquake in the Mexico City area. The availability of detailed geological, geophysical, geotechnical, and seismological data allowed for the creation of a large-scale (60 km × 60 km in plan, 10 km in depth) heterogeneous 3D numerical model of the Mexico City area, dimensioned to accurately propagate frequencies up to about 1.3 Hz. The results of numerical simulations are validated against the ground motion recordings of the July 17, 2019, Mw3.2 earthquake, with peak ground acceleration exceeding 0.3 g about 1 km away from the epicenter. A good agreement with records is found, quantitatively evaluated through goodness-of-fit checks. Furthermore, for the lake zone, the simulated decay trend of the peak ground velocity with epicentral distance is reasonably close to the observations, for both horizontal and vertical components. In spite of some limitations, the simulations are successful to provide a realistic picture of seismic wave propagation both in the hill and in the lake zones of Mexico City, including the onset of long-duration quasi-monochromatic ground motion in the basin, with strong amplification at low frequencies (between 0.4 and 0.7 Hz). The numerical results also suggest that surface waves, with predominant prograde particle motion at the ground surface and large ellipticities, dominate the wavefield in the lake zone. Based on these positive outcomes, we conclude that this numerical model may be useful for both a better insight into the seismic response of the Valley of Mexico and the simulation of ground motions during larger-magnitude earthquakes, to generate improved seismic damage scenarios in Mexico City.
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墨西哥谷地面运动的三维数值模拟:以2019年7月17日Mw3.2地震为例
在本研究中,采用基于三维物理的数值方法,基于谱元数值代码SPEED,模拟了墨西哥城地区局地地震引起的地震波传播。详细的地质、地球物理、岩土和地震学数据的可用性允许创建墨西哥城地区的大规模(60公里× 60公里的平面,10公里的深度)非均匀三维数值模型,其尺寸精确地传播频率高达约1.3赫兹。数值模拟结果与2019年7月17日Mw3.2级地震的地面运动记录进行了验证,该地震距离震中约1公里处的地面加速度峰值超过0.3 g。找到与记录的良好一致性,并通过拟合优度检查进行定量评估。此外,在湖区,地面峰值速度随震中距离的衰减趋势与观测值相当接近,无论是水平分量还是垂直分量。尽管存在一些局限性,但模拟成功地提供了墨西哥城山区和湖区地震波传播的真实图像,包括盆地中长时间准单色地面运动的开始,低频(0.4和0.7 Hz之间)有很强的放大。数值计算结果还表明,在湖区波场中,表面波主要以地表推进粒子运动为主,椭圆率大。基于这些积极的结果,我们得出结论,该数值模型可能有助于更好地了解墨西哥谷的地震反应和模拟大震级地震期间的地面运动,从而生成改进的墨西哥城地震破坏情景。
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来源期刊
Earthquake Spectra
Earthquake Spectra 工程技术-工程:地质
CiteScore
8.40
自引率
12.00%
发文量
88
审稿时长
6-12 weeks
期刊介绍: Earthquake Spectra, the professional peer-reviewed journal of the Earthquake Engineering Research Institute (EERI), serves as the publication of record for the development of earthquake engineering practice, earthquake codes and regulations, earthquake public policy, and earthquake investigation reports. The journal is published quarterly in both printed and online editions in February, May, August, and November, with additional special edition issues. EERI established Earthquake Spectra with the purpose of improving the practice of earthquake hazards mitigation, preparedness, and recovery — serving the informational needs of the diverse professionals engaged in earthquake risk reduction: civil, geotechnical, mechanical, and structural engineers; geologists, seismologists, and other earth scientists; architects and city planners; public officials; social scientists; and researchers.
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