Strong motion from surface waves in deep sedimentary basins

ABSTRACT Sedimentary basins in the Puget Sound region, Washington State, increase ground-motion intensity and duration of shaking during local earthquakes. We analyze Pacific Northwest Seismic Network and U.S. Geological Survey strong-motion recordings of five local earthquakes (M 3.9–6.8), including the 2001 Nisqually earthquake, to characterize sedimentary basin effects within the Seattle and Tacoma basins. We observe basin-edge generated surface waves at sites within the Seattle basin for most ray paths that cross the Seattle fault zone. We also note previously undocumented basin-edge surface waves in the Tacoma basin during one of the local earthquakes. To place quantitative constraints on basin amplification, we determine amplification factors by computing the spectral ratios of inside-basin sites to outside-basin sites at 1, 2, 3, and 5 s periods. Ground shaking is amplified in the Seattle basin for all the earthquakes analyzed and for a subset of events in the Tacoma basin. We find that the largest amplification factors in the Seattle basin are produced by a shallow earthquake located to the southwest of the basin. Our observation suggests that future shallow crustal and megathrust earthquakes rupturing west of the Puget Lowland will produce greater amplification within the Seattle basin than has been seen for intraslab events. We also perform ground-motion simulations using a finite-difference method to validate a 3D Cascadia velocity model (CVM) by comparing properties of observed and synthetic waveforms up to a frequency of 1 Hz. Basin-edge effects are well reproduced in the Seattle basin, but are less well resolved in the Tacoma basin. Continued study of basin effects in the Tacoma basin would improve the CVM.

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VS30 at three strong-motion recording stations in Napa and Solano Counties, California—Lovall Valley Road, Broadway Street and Sereno Drive in Vallejo, and Vallejo Fire Station—Calculations determined from S-wave refraction tomography and multichannel analysis of surface waves (Rayleigh and Love)

Open-File Report ◽

10.3133/ofr20181162 ◽

2018 ◽

Author(s):

Joanne H. Chan ◽

Rufus D. Catchings ◽

Mark R. Goldman ◽

Coyn J. Criley

Keyword(s):

Surface Waves ◽

Strong Motion ◽

S Wave ◽

Wave Refraction ◽

Multichannel Analysis ◽

Refraction Tomography ◽

Fire Station ◽

Strong Motion Recording

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Strong Motion Simulation of the 1987 Chiba-ken-toho-oki Earthquake (MJ6.7) Using Stochastic Green's Function Generation Method Empirically Considering Surface Waves and Scattering Waves

Journal of Japan Association for Earthquake Engineering ◽

10.5610/jaee.15.7_34 ◽

2015 ◽

Vol 15 (7) ◽

pp. 7_34-7_48

Author(s):

Toshimi SATOH

Keyword(s):

Green’S Function ◽

Surface Waves ◽

Green's Function ◽

Strong Motion ◽

Motion Simulation ◽

Function Generation ◽

Strong Motion Simulation

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Shear-wave velocity of the ground near sixty California strong motion recording sites by the spectral analysis of surface waves (SASW) method and harmonic-wave sources

Open-File Report ◽

10.3133/ofr20051366 ◽

2005 ◽

Cited By ~ 4

Author(s):

Robert Kayen ◽

Eric Thompson ◽

Diane L. Minasian ◽

Brad Carkin

Keyword(s):

Spectral Analysis ◽

Surface Waves ◽

Shear Wave ◽

Wave Velocity ◽

Shear Wave Velocity ◽

Harmonic Wave ◽

Strong Motion ◽

Strong Motion Recording

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Investigation of Soil Characterization in Hatay Province in Turkey by Using Seismic Refraction, Multichannel Analysis of Surface Waves and Microtremor

Earth Sciences Research Journal ◽

10.15446/esrj.v24n4.79123 ◽

2021 ◽

Vol 24 (4) ◽

pp. 473-484

Author(s):

Cengiz Kurtuluş ◽

Ibrahim Sertcelik ◽

Fadime Sertçelik ◽

Hamdullah Livaoğlu ◽

Cüneyt Şaş

Keyword(s):

Surface Waves ◽

Shear Wave ◽

Wave Velocity ◽

Shear Wave Velocity ◽

Seismic Refraction ◽

Strong Motion ◽

Site Classification ◽

Eurocode 8 ◽

Site Class ◽

Multichannel Analysis

In this study, shallow seismic surveys, including seismic refraction, Multichannel Analysis of Surface Waves (MASW), Refraction Microtremor (ReMi), and Microtremor measurements were conducted to estimate site characterization at 26 strong-motion stations of AFAD (Disaster and Emergency Management Presidency) in the province of Hatay, situated in one of the most seismically active regions in southern Turkey. The Horizontal to vertical spectral ratio (HVSR) technique was applied, using smoothed Fourier spectra derived from a long duration series to determine dominant frequency values at different amplification levels. Shear wave velocity up to 30 m of the ground was detected with MASW analysis. In the ReMi analysis, up to 80 m was reached with a corresponding average of 650 m/s shear wave velocity. The shear wave velocities estimated by the MASW method up to 30 m were compared with those found by the ReMi method, and they were observed to be very compatible. The province of Hatay was classified according to Vs30 based NEHRP Provisions, Eurocode-8, the Turkish Building Earthquake Regulation (TBDY-2018), and Rodriguez-Marek et al. (2001). The shear-wave velocity (Vs30), Horizontal to Vertical ratio’s (H/V) peak amplitude, dominant period, and site class of each site were determined. The H/V peak amplitudes range between 1.9 and 7.6, while the predominant periods vary from 0.23 sec to 2.94sec in the study area. These results are investigated to explain the consistency of site classification schemes.

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Surface-wave dispersion analysis in Mexico City

Bulletin of the Seismological Society of America ◽

10.1785/bssa0850041116 ◽

1995 ◽

Vol 85 (4) ◽

pp. 1116-1126

Author(s):

Francisco J. Chávez-García ◽

Jaime Ramos-Martínez ◽

Evangelina Romero-Jiménez

Keyword(s):

Surface Wave ◽

Surface Waves ◽

Ground Motion ◽

Mexico City ◽

Rayleigh Waves ◽

Strong Motion ◽

Clay Layer ◽

Period Range ◽

Wave Trains ◽

Refraction Data

Abstract In this article, we present an observational investigation of ground motion at Mexico City focused on surface waves. Our purpose is 2-fold; first, to understand incident ground motion during the great Michoacán earthquake of 19 September 1985, and second, to characterize surface waves propagating in the lake-bed zone. To this end we analyze the strong-motion records obtained at Mexico City for the large (MS = 8.1) earthquake of 19 September 1985. It is shown that, in the low-frequency range, we observe the Rayleigh fundamental mode in both the vertical and the radial components, and the Love fundamental mode in the transverse component at all the strong-motion stations. The vertical component also shows the first higher mode of Rayleigh waves. We use a very broadband record obtained at station CU for the smaller (MS = 6.7) earthquake of 14 May 1993 to verify that the dispersion computed from the model of Campillo et al. (1989) represents well the average surface-wave propagation between the coast and Mexico City in the 7- to 10-sec period range. We use this result to assign absolute times to the strong-motion records of the Michoacán event. This allowed us to identify additional wave trains that propagate laterally in directions other than great circle in the 3- to 5-sec period range. These wave trains are identified as Love waves. In a second analysis, we study a set of refraction data obtained during a small-scale (250 m) experiment on the virgin clay of the lake-bed zone. Phase-velocity dispersion curves for several modes of Rayleigh waves are identified in the refraction data and inverted to obtain an S-wave velocity profile. This profile is used as the uppermost layering in a 2D model of Mexico City valley. The results of numerical simulation show that surface waves generated by lateral finiteness of the clay layer suffer large dispersion and attenuation. We conclude that surface waves generated by the lateral heterogeneity of the upper-most stratigraphy very significantly affect ground motion near the edge of the valley, but their importance is negligible for distances larger than 1.5 km from the edge. Thus, locally generated surface waves propagating through the clay layer cannot explain late arrivals observed for the 1985 event. We suggest that the long duration of strong motion is due to the interaction between lateral propagation of waves guided by deep layers (1 to 4 km) and the surficial clay layer. This interaction is possible by the coincidence of the dominant frequency of the uppermost layers and the frequency of the deeply guided waves.

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Ensemble ShakeMaps for Magnitude 9 Earthquakes on the Cascadia Subduction Zone

Seismological Research Letters ◽

10.1785/0220200240 ◽

2020 ◽

Vol 92 (1) ◽

pp. 199-211

Author(s):

Erin A. Wirth ◽

Alex Grant ◽

Nasser A. Marafi ◽

Arthur D. Frankel

Keyword(s):

Ground Motion ◽

Strong Motion ◽

Sedimentary Basins ◽

Earthquake Rupture ◽

Logic Tree ◽

Ground Shaking ◽

Amplification Factors ◽

Earthquake Scenarios ◽

The Pacific ◽

Tree Approach

Abstract We develop ensemble ShakeMaps for various magnitude 9 (M 9) earthquakes on the Cascadia megathrust. Ground-shaking estimates are based on 30 M 9 Cascadia earthquake scenarios, which were selected using a logic-tree approach that varied the hypocenter location, down-dip rupture limit, slip distribution, and location of strong-motion-generating subevents. In a previous work, Frankel et al. (2018) used a hybrid approach (i.e., 3D deterministic simulations for frequencies <1 Hz and stochastic synthetics for frequencies >1 Hz) and uniform site amplification factors to create broadband seismograms from this set of 30 earthquake scenarios. Here, we expand on this work by computing site-specific amplification factors for the Pacific Northwest and applying these factors to the ground-motion estimates derived from Frankel et al. (2018). In addition, we use empirical ground-motion models (GMMs) to expand the ground-shaking estimates beyond the original model extent of Frankel et al. (2018) to cover all of Washington State, Oregon, northern California, and southern British Columbia to facilitate the use of these ensemble ShakeMaps in region-wide risk assessments and scenario planning exercises. Using this updated set of 30 M 9 Cascadia earthquake scenarios, we present ensemble ShakeMaps for the median, 2nd, 16th, 84th, and 98th percentile ground-motion intensity measures. Whereas traditional scenario ShakeMaps are based on a single hypothetical earthquake rupture, our ensemble ShakeMaps take advantage of a logic-tree approach to estimating ground motions from multiple earthquake rupture scenarios. In addition, 3D earthquake simulations capture important features such as strong ground-motion amplification in the Pacific Northwest’s sedimentary basins, which are not well represented in the empirical GMMs that compose traditional scenario ShakeMaps. Overall, our results highlight the importance of strong-motion-generating subevents for coastal sites, as well as the amplification of long-period ground shaking in deep sedimentary basins, compared with previous scenario ShakeMaps for Cascadia.

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