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11 results on '"Bonilla, L F"'

3. Prenolin: International benchmark on 1D nonlinear: Site-response analysis—validation phase exercise

Author

Mecánica Aplicada, Régnier J., Bonilla L.-F., Bard P.-Y., Bertrand E., Hollender F., Kawase H., Sicilia D., Arduino P., Amorosi A., Asimaki D., Boldini D., Chen L., Chiaradonna A., Demartin F., Elgamal A., Falcone G., Foerster E., Foti S., Garini E., Gazetas G., Gélis C., Ghofrani A., Giannakou A., Gingery J., Glinsky N., Harmon J., Hashash Y., Iai S., Kramer S., Kontoe S., Kristek J., Lanzo G., Lernia A.D., Lopez-Caballero F., Marot M., McAllister G., Mercerat E.D., Moczo P., Montoya-Noguera S., Musgrove M., Nieto-Ferro A., Pagliaroli A., Passeri F., Richterova A., Sajana S., Santisi D’Avila M.P., Shi J., Silvestri F., Taiebat M., Tropeano G., Vandeputte D., Verrucci L., Mecánica Aplicada, Régnier J., Bonilla L.-F., Bard P.-Y., Bertrand E., Hollender F., Kawase H., Sicilia D., Arduino P., Amorosi A., Asimaki D., Boldini D., Chen L., Chiaradonna A., Demartin F., Elgamal A., Falcone G., Foerster E., Foti S., Garini E., Gazetas G., Gélis C., Ghofrani A., Giannakou A., Gingery J., Glinsky N., Harmon J., Hashash Y., Iai S., Kramer S., Kontoe S., Kristek J., Lanzo G., Lernia A.D., Lopez-Caballero F., Marot M., McAllister G., Mercerat E.D., Moczo P., Montoya-Noguera S., Musgrove M., Nieto-Ferro A., Pagliaroli A., Passeri F., Richterova A., Sajana S., Santisi D’Avila M.P., Shi J., Silvestri F., Taiebat M., Tropeano G., Vandeputte D., and Verrucci L.

Abstract

This article presents the main results of the validation phase of the PRENOLIN project. PRENOLIN is an international benchmark on 1D nonlinear (NL) site-response analysis. This project involved 19 teams with 23 different codes tested. It was divided into two phases; with the first phase verifying the numerical solution of these codes on idealized soil profiles using simple signals and real seismic records. The second phase described in this article referred to code validation for the analysis of real instrumented sites. This validation phase was performed on two sites (KSRH10 and Sendai) of the Japanese strong-motion networks KiK-net and Port and Airport Research Institute (PARI), respectively, with a pair of accelerometers at surface and depth. Extensive additional site characterizations were performed at both sites involving in situ and laboratory measurements of the soil properties. At each site, sets of input motions were selected to represent different peak ground acceleration (PGA) and frequency content. It was found that the code-to-code variability given by the standard deviation of the computed surface-response spectra is around 0.1 (in log10 scale) regardless of the site and input motions. This indicates a quite large influence of the numerical methods on site-effect assessment and more generally on seismic hazard. Besides, it was observed that sitespecific measurements are of primary importance for defining the input data in siteresponse analysis. The NL parameters obtained from the laboratory measurements should be compared with curves coming from the literature. Finally, the lessons learned from this exercise are synthesized, resulting also in a few recommendations for future benchmarking studies, and the use of 1D NL, total stress site-response analysis. © 2018, Seismological Society of America. All rights reserved.

Published
2021

6. Profiling the Quito basin (Ecuador) using seismic ambient noise.

Author

Pacheco, D, Mercerat, E D, Courboulex, F, Bonilla, L F, Laurendeau, A, and Alvarado, A

Subjects
SURFACE waves (Seismic waves), MICROSEISMS, WAVE amplification, GREEN'S functions, RAYLEIGH waves, SEISMIC waves, ADAKITE, FAULT zones
Abstract

Quito, the capital of Ecuador, with more than 2.5 M inhabitants, is exposed to a high seismic hazard due to its proximity to the Pacific subduction zone and active crustal faults, both capable of generating significant earthquakes. Furthermore, the city is located in an intermontane piggy-back basin prone to seismic wave amplification. To understand the basin's seismic response and characterize its geological structure, 20 broad and medium frequency band seismic stations were deployed in Quito's urban area between May 2016 and July 2018 that continuously recorded ambient seismic noise. We first compute horizontal-to-vertical spectral ratios to determine the resonant frequency distribution in the entire basin. Secondly, we cross-correlate seismic stations operating simultaneously to retrieve interstations surface-wave Green's functions in the frequency range of 0.1–2 Hz. We find that Love waves travelling in the basin's longitudinal direction (NNE–SSW) show much clearer correlograms than those from Rayleigh waves. We then compute Love wave phase-velocity dispersion curves and invert them in conjunction with the HVSR curves to obtain shear-wave velocity profiles throughout the city. The inversions highlight a clear difference in the basin's structure between its northern and southern parts. In the centre and northern areas, the estimated basin depth and mean shear-wave velocity are about 200 m and 1800 ms−1, respectively, showing resonance frequency values between 0.6 and 0.7 Hz. On the contrary, the basement's depth and shear-wave velocity in the southern part are about 900 m and 2500 ms−1, having a low resonance frequency value of around 0.3 Hz. This difference in structure between the centre-north and the south of the basin explains the spatial distribution of low-frequency seismic amplifications observed during the M w 7.8 Pedernales earthquake in April 2016 in Quito. [ABSTRACT FROM AUTHOR]

Published
2022
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7. Effects of 2-D random velocity perturbations on 2-D SH short-period ground motion simulations in the basin of Nice, France.

Author

Tchawe, F N, Gelis, C, BONILLA, L F, and Lopez-Caballero, F

Subjects
EARTHQUAKE hazard analysis, SPECTRAL element method, SURFACE waves (Seismic waves), VELOCITY, THEORY of wave motion, SEISMIC response
Abstract

Some geological configurations, like sedimentary basins, are prone to site effects. Basins are often composed of different geological layers whose properties are generally considered as spatially homogeneous or smoothly varying. In this study, we address the influence of small-scale velocity fluctuations on seismic response. For this purpose, we use the spectral element method to model the 2-D SH wave propagation on a basin of 1.1 km long and ≈ 60 m deep, representing a 2-D profile in the city of Nice, France. The velocity fluctuations are modelled statistically as a random process characterized by a Von Karman autocorrelation function and are superimposed to the deterministic model. We assess the influence of the amplitude and correlation length of the random velocities on the surface ground motion. We vary the autocorrelation function's parameters and compute seismic wavefields in 10 random realizations of the stochastic models. The analyses of our results focus on the envelope and phase differences between the waveforms computed in the random and deterministic models; on the variability of ground motion intensity measures, such as the peak ground velocity, the pseudo-spectral acceleration response; and the 2-D basin response (transfer function). We find that the amplitude of fluctuations has a greater effect on the ground motion variability than the correlation length. Depending on the random medium realization, the ground motion in one stochastic model can be locally amplified or deamplified with respect to the reference model due to the presence of high or low velocity contrasts, respectively. When computing the mean amplification of different random realizations, the results may be smaller than those of the reference media due to the smoothing effect of the average. This study highlights the importance of knowing the site properties at different scales, particularly at small scales, for proper seismic hazard assessment. [ABSTRACT FROM AUTHOR]

Published
2021
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8. METACity-Quito : a semi-dense urban seismic network deployed to analyze the concept of metamaterial for the future design of seismic-proof cities

Author

Gueguen, P., Mercerat, E. D., Singaucho, J. C., Aubert, C., Barros, J. G., Bonilla, L. F., Cripstyani, M., Douste-Bacque, I., Langlaude, P., Mercier, Stéphane, Pacheco, D., Pernoud, M., Perrault, M., Pondaven, I., and Wolyniec, D.

Abstract

The presence of multiscale interactions means that the complex urban wavefield must be observed and analyzed in order to understand seismic ground motion in urban environments. Originally called site-city interaction, the interactions between soil and structures, structures and soil, and between structures contribute to the modification of urban seismic ground motion. This may affect the lateral variability of the ground motion observed in relation to earthquake damage, the characterization of site effects in urban areas, and also the response of civil engineering structures designed without consideration of the immediate urban environment. The METACity-Quito experiment was designed to take accurate measurements of the effects of the resonator array formed by structures in the seismic wavefield, in the manner of an urban metamaterial. Current applications in the fields of physics, acoustics and, more recently, geophysics have shown the existence of forbidden bands, that is, frequencies at which seismic energy vanishes. This concept could help to understand the heterogeneous distribution of damage in urban areas as well as to imagine the future design of seismic-proof cities.

Published
2019

9. Estimation of non-linear site response in a deep Alpine valley

Author

Roten, D., Fäh, D., Bonilla, L. F., Alvarez-Rubio, S., Weber, T. M., Laue, J., Roten, D., Fäh, D., Bonilla, L. F., Alvarez-Rubio, S., Weber, T. M., and Laue, J.

Abstract

We simulate non-linear behaviour of soils during strong ground motion in the Rhône valley in southern Switzerland. Previous studies of the site response using weak ground motion, ambient noise and linear 3-D FD simulations suggest that the 2-D structure of the basin will lead to amplification factors of up to 12 in the frequency band between 0.5 and 10 Hz. To estimate the importance of non-linear soil behaviour during strong ground motion in the Rhône valley we simulate the response of a superficial soft layer with a fully non-linear 1-D finite difference code. The non-linear wave propagator is based on an effective stress constitutive soil model capable of predicting pore pressure evolution due to shear. We determine the required dilatancy parameters from laboratory analysis of soil samples using cyclic triaxial tests. In order to include the effect of the strong 2-D structure in our non-linear analysis synthetic seismograms are convolved with the transfer function of the basin and then propagated through a 1-D non-linear layer. We find that reduced amplification due to soil non-linearity can be expected at rock accelerations above 0.5 ms−2, and that de-amplification occurs at ground motion levels of approximately 2 ms−2. Nevertheless, the spectral accelerations simulated for the valley centre are still exceeding the design spectra at about 0.5 Hz for magnitudes above 6.0, which reflects the strong amplification of ground motion by the deep 2-D resonance of the basin. For frequencies above 1 Hz the design spectra are generally in agreement with the strongest simulated accelerations. We evaluate the occurrence of soil failure using the 5 per cent strain criterion as a function of hypocentral distance and magnitude. Results confirm observations of liquefaction reported after the 1855 Mw 6.4 earthquake of Visp, and they suggest that soil liquefaction may occur at distances beyond those predicted by empirical relations in the valley. Near the basin edge, however, the s

Published
2017

10. High-frequency ground motion amplification during the 2011 Tohoku earthquake explained by soil dilatancy

Author

Roten, D., Fäh, D., Bonilla, L. F., Roten, D., Fäh, D., and Bonilla, L. F.

Abstract

Ground motions of the 2011 Tohoku earthquake recorded at Onahama port (Iwaki, Fukushima prefecture) rank among the highest accelerations ever observed, with the peak amplitude of the 3-D acceleration vector approaching 2g. The response of the site was distinctively non-linear, as indicated by the presence of horizontal acceleration spikes which have been linked to cyclic mobility during similar observations. Compared to records of weak ground motions, the response of the site during the Mw 9.1 earthquake was characterized by increased amplification at frequencies above 10 Hz and in peak ground acceleration. This behaviour contrasts with the more common non-linear response encountered at non-liquefiable sites, which results in deamplification at higher frequencies. We simulate propagation of SH waves through the dense sand deposit using a non-linear finite difference code that is capable of modelling the development of excess pore water pressure. Dynamic soil parameters are calibrated using a direct search method that minimizes the difference between observed and simulated acceleration envelopes and response spectra. The finite difference simulations yield surface acceleration time-series that are consistent with the observations in shape and amplitude, pointing towards soil dilatancy as a likely explanation for the high-frequency pulses recorded at Onahama port. The simulations also suggest that the occurrence of high-frequency spikes coincided with a rapid increase in pore water pressure in the upper part of the sand deposit between 145 and 170 s. This sudden increase is possibly linked to a burst of high-frequency energy from a large slip patch below the Iwaki region

Published
2017

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