Correction to: Ground Motion Amplification Induced by Shallow Circular Tunnel in Soft Soil

AbstractIn this paper the site categorization criteria and the corresponding site amplification factors proposed in the 2021 draft of Part 1 of Eurocode 8 (2021-draft, CEN/TC250/SC8 Working Draft N1017) are first introduced and compared with the current version of Eurocode 8, as well as with site amplification factors from recent empirical ground motion prediction equations. Afterwards, these values are checked by two approaches. First, a wide dataset of strong motion records is built, where recording stations are classified according to 2021-draft, and the spectral amplifications are empirically estimated computing the site-to-site residuals from regional and global ground motion models for reference rock conditions. Second, a comprehensive parametric numerical study of one-dimensional (1D) site amplification is carried out, based on randomly generated shear-wave velocity profiles, classified according to the new criteria. A reasonably good agreement is found by both approaches. The most relevant discrepancies occur for the shallow soft soil conditions (soil category E) that, owing to the complex interaction of shear wave velocity, soil deposit thickness and frequency range of the excitation, show the largest scatter both in terms of records and of 1D numerical simulations. Furthermore, 1D numerical simulations for soft soil conditions tend to provide lower site amplification factors than 2021-draft, as well as lower than the corresponding site-to-site residuals from records, because of higher impact of non-linear (NL) site effects in the simulations. A site-specific study on NL effects at three KiK-net stations with a significantly large amount of high-intensity recorded ground motions gives support to the 2021-draft NL reduction factors, although the very limited number of recording stations allowing such analysis prevents deriving more general implications. In the presence of such controversial arguments, it is reasonable that a standard should adopt a prudent solution, with a limited reduction of the site amplification factors to account for NL soil response, while leaving the possibility to carry out site-specific estimations of such factors when sufficient information is available to model the ground strain dependency of local soil properties.

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Ground-motion amplification at the Colle di Roio ridge, central Italy: a combined effect of stratigraphy and topography

Geophysical Journal International ◽

10.1093/gji/ggw120 ◽

2016 ◽

Vol 206 (1) ◽

pp. 1-18 ◽

Cited By ~ 20

Author(s):

S. Hailemikael ◽

L. Lenti ◽

S. Martino ◽

A. Paciello ◽

D. Rossi ◽

...

Keyword(s):

Ground Motion ◽

Central Italy ◽

Combined Effect ◽

Ground Motion Amplification

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Near-Surface Seismic Studies To Estimate Potential Earthquake Ground Motion Amplification At A Thick Soil Site In The Ottawa River Valley, Canada

10.3997/2214-4609-pdb.192.ssi_6 ◽

2001 ◽

Author(s):

Beatriz Benjumea ◽

Jim A. Hunter ◽

Susan E. Pullan ◽

Robert A. Burns ◽

Ron L. Good

Keyword(s):

Ground Motion ◽

River Valley ◽

Earthquake Ground Motion ◽

Near Surface ◽

Ground Motion Amplification ◽

Ottawa River ◽

Soil Site

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Study on Ground Motion Intensity Measures for Seismic Response Evaluation of Circular Tunnel

IOP Conference Series Earth and Environmental Science ◽

10.1088/1755-1315/455/1/012164 ◽

2020 ◽

Vol 455 ◽

pp. 012164

Author(s):

Chengming Zhang ◽

Zilan Zhong ◽

Mi Zhao

Keyword(s):

Seismic Response ◽

Ground Motion ◽

Response Evaluation ◽

Circular Tunnel ◽

Intensity Measures

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Physical stratigraphy and geotechnical properties controlling the local seismic response in explosive volcanic settings: the Stracciacappa maar (central Italy)

Bulletin of Engineering Geology and the Environment ◽

10.1007/s10064-020-01925-5 ◽

2020 ◽

Vol 80 (1) ◽

pp. 179-199

Author(s):

M. Moscatelli ◽

G. Vignaroli ◽

A. Pagliaroli ◽

R. Razzano ◽

A. Avalle ◽

...

Keyword(s):

Seismic Response ◽

Ground Motion ◽

Central Italy ◽

Volcanic Event ◽

Ground Motion Amplification ◽

Local Seismic Response ◽

Single Station ◽

Seismic Scenarios ◽

Physical Stratigraphy ◽

Subsoil Model

AbstractNowadays, policies addressed to prevention and mitigation of seismic risk need a consolidated methodology finalised to the assessment of local seismic response in explosive volcanic settings. The quantitative reconstruction of the subsoil model provides a key instrument to understand how the geometry and the internal architecture of outcropping and buried geological units have influence on the propagation of seismic waves. On this regard, we present a multidisciplinary approach in the test area of the Stracciacappa maar (Sabatini Volcanic District, central Italy), with the aim to reconstruct its physical stratigraphy and to discuss how subsoil heterogeneities control the 1D and 2D local seismic response in such a volcanic setting. We first introduce a new multidisciplinary dataset, including geological (fieldwork and log from a 45-m-thick continuous coring borehole), geophysical (electrical resistivity tomographies, single station noise measurements, and 2D passive seismic arrays), and geotechnical (simple shear tests performed on undisturbed samples) approaches. Then, we reconstruct the subsoil model for the Stracciacappa maar in terms of vertical setting and distribution of its mechanical lithotypes, which we investigate for 1D and 2D finite element site response analyses through the application of two different seismic scenarios: a volcanic event and a tectonic event. The numerical modelling documents a significant ground motion amplification (in the 1–1.5 Hz range) revealed for both seismic scenarios, with a maximum within the centre of the maar. The ground motion amplification is related to both 1D and 2D phenomena including lithological heterogeneity within the upper part of the maar section and interaction of direct S-waves with Rayleigh waves generated at edges of the most superficial lithotypes. Finally, we use these insights to associate the expected distribution of ground motion amplification with the physical stratigraphy of an explosive volcanic setting, with insights for seismic microzonation studies and local seismic response assessment in populated environments.

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