Simulation of 0–7.5 Hz physics-based nonlinear ground motions for maximum credible earthquake scenarios at the Long Valley Dam, CA

Earthquake Spectra Pub Date : 2024-02-11 DOI:10.1177/87552930231226135

Te-Yang Yeh, Kim B. Olsen

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Abstract

We have conducted three-dimensional (3D) 0–7.5 Hz physics-based wave propagation simulations to model the seismic response of the Long Valley Dam (LVD), which has formed Lake Crowley in Central California, to estimate peak ground motions and settlement of the dam expected during maximum credible earthquake (MCE) scenarios on the nearby Hilton Creek Fault (HCF). We calibrated the velocity structure, anelastic attenuation model, and the overall elastic properties of the dam via linear simulations of a Mw 3.7 event as well as the Mw 6.2 Chalfant Valley earthquake of 1986, constrained by observed ground motions on and nearby the LVD. The Statewide California Earthquake Center (SCEC) Community Velocity Model CVM-S4.26.M01 superimposed with a geotechnical layer using [Formula: see text] information tapered from the surface to a 700-m depth was used in the simulations. We found optimal fit of simulated and observed ground motions at the LVD using frequency-independent attenuation of [Formula: see text] ([Formula: see text] in m/s). Using the calibrated model, we simulated 3D nonlinear ground motions at the LVD for Mw 6.6 rupture scenarios on the HCF using an Iwan-type, multi-yield-surface technique. We use a two-step method where the computationally expensive nonlinear calculations were carried out in a small domain with the plane wave excitation along the bottom boundary obtained from a full-domain 3D linear finite-fault simulation. Our nonlinear MCE simulation results show that peak ground velocities (PGVs) and peak ground accelerations (PGAs) as high as 72 cm/s and 0.55 g, respectively, can be expected at the crest of the LVD. Compared with linear ground motion simulation results, our results show that Iwan nonlinear damping reduces PGAs on the dam crest by up to a factor of 8 and increasingly depletes the high-frequency content of the waves toward the dam crest. We find horizontal relative displacements of the material inside the dam of up to [Formula: see text] and up to [Formula: see text] of vertical subsidence, equivalent to 1% of the dam height.

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加利福尼亚州长谷大坝 0-7.5 Hz 基于物理的非线性地面运动模拟，适用于最大可信地震场景

我们进行了基于物理的 0-7.5 Hz 波传播三维（3D）模拟，对加利福尼亚州中部形成克劳利湖的长谷大坝（LVD）的地震响应进行建模，以估算在附近的希尔顿溪断层（HCF）上发生最大可信地震（MCE）时大坝的峰值地面运动和沉降。我们通过对 Mw 3.7 地震和 1986 年 Mw 6.2 Chalfant 山谷地震的线性模拟，校准了大坝的速度结构、无弹性衰减模型和整体弹性特性，并以 LVD 上和附近的观测地面运动为约束。模拟中使用了全加州地震中心 (SCEC) 的社区速度模型 CVM-S4.26.M01，该模型叠加了使用[计算公式：见正文]信息的岩土层，该岩土层从地表到 700 米深处逐渐变细。我们使用与频率无关的[计算公式：见正文]衰减（[计算公式：见正文]，单位为 m/s）对低地压区的模拟地动和观测地动进行了最佳拟合。利用校准后的模型，我们采用 Iwan 型多屈服面技术模拟了 HCF 上 Mw 6.6 断裂情况下 LVD 处的三维非线性地面运动。我们采用了两步法，其中计算成本高昂的非线性计算是在一个小域内进行的，而平面波激励则是沿着从全域三维线性有限故障模拟中获得的底部边界进行的。我们的非线性 MCE 模拟结果表明，预计在 LVD 波峰处的峰值地面速度 (PGV) 和峰值地面加速度 (PGA) 分别高达 72 cm/s 和 0.55 g。与线性地面运动模拟结果相比，我们的结果显示 Iwan 非线性阻尼将坝顶的峰值地面加速度降低了 8 倍之多，并使波浪的高频含量向坝顶方向逐渐减弱。我们发现坝内材料的水平相对位移高达[公式：见正文]，垂直下沉高达[公式：见正文]，相当于坝高的 1%。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Earthquake Spectra

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