Your search keyword '"Mariniere, J"' showing total 4 results

1. Comparison of observed ground-motion attenuation for the 2016/04/16 Mw7.8 Ecuador megathrust earthquake and its two largest aftershocks with existing ground-motion prediction equations

Author

Beauval, C., Marinière, J., Laurendeau, A., Singaucho, J-C., Viracucha, C., Vallée, M., Maufroy, E., Mercerat, D., Yepes, H., Ruiz, M., and Alvarado, A.

Subjects

Physics - Geophysics

Abstract

A megathrust subduction earthquake (Mw7.8) struck the coast of Ecuador on April 16th, 2016 at 23h58 UTC. This earthquake is one of the best-recorded megathrust events up to date. Besides the mainshock, two large aftershocks have been recorded on May 18th, 2016, at 7h57 (Mw 6.7) and 16h46 (Mw6.9). These data make a significant contribution for understanding the attenuation of ground motions in Ecuador. Peak ground accelerations and spectral accelerations are compared with four ground-motion prediction equations developed for interface earthquakes, the global Abrahamson et al. (2016) model, the Japanese equations Zhao et al. (2006) and Ghofrani and Atkinson (2014), and one Chilean equation Montalva et al. (2016). The four tested GMPEs are providing rather close predictions for the mainshock at distances up to 200km. However, our results show that high-frequency attenuation is greater for backarc sites, thus Zetal2016 and Metal2016, which are not taking into account this difference, are not considered further. Residual analyses show that G&A14 and Aetal2016 are well predicting the attenuation of ground motions for the mainshock. Comparisons of aftershock observations with Aetal2016 predictions indicate that the GMPE provide reasonable fit to the attenuation rates observed. The event terms of the Mw6.7 and Mw6.9 events are positive but within the expected scatter from worldwide similar earthquakes. The intra-event standard deviations are higher than the intraevent variability of the model, which is partly related to the poorly constrained VS30 proxys., Comment: article

Published

2018

2. Geodetic evidence for shallow creep along the Quito fault, Ecuador

Author

Mariniere, J, primary, Nocquet, J-M, additional, Beauval, C, additional, Champenois, J, additional, Audin, L, additional, Alvarado, A, additional, Baize, S, additional, and Socquet, A, additional

Published

2019

3. National Seismic Hazard Maps for Ecuador

Author

Beauval, C., Yepes, H., Mariniere, J., Audin, L., Alvarado, A., Baize, S., Cotton, F., and Drouet, S.

Published

2017

4. Geodetic evidence for shallow creep along the Quito fault, Ecuador.

Author

Mariniere, J, Nocquet, J-M, Beauval, C, Champenois, J, Audin, L, Alvarado, A, Baize, S, and Socquet, A

Subjects

*PALEOSEISMOLOGY, *SURFACE waves (Seismic waves), *SYNTHETIC aperture radar, *GLOBAL Positioning System, *BUILDING design & construction, *POPULATION density, *RADAR interferometry

Abstract

Quito, the capital city of Ecuador hosting ∼2 million inhabitants, lies on the hanging wall of a ∼60-km-long reverse fault offsetting the Inter-Andean Valley in the northern Andes. Such an active fault poses a significant risk, enhanced by the high density of population and overall poor building construction quality. Here, we constrain the present-day strain accumulation associated with the Quito fault with new Global Positioning System (GPS) data and Persistent Scatterer Interferometric Synthetic Aperture Radar (PS-InSAR) analysis. Far field GPS data indicate 3–5 mm yr–1 of horizontal shortening accommodated across the fault system. In the central segment of the fault, both GPS and PS-InSAR results highlight a sharp velocity gradient, which attests for creep taking place along the shallowest portion of the fault. Smoother velocity gradients observed along the other segments indicate that the amount of shallow creep decreases north and south of the central segment. 2-D elastic models using GPS horizontal velocity indicate very shallow (<1 km) locking depth for the central segment, increasing to a few kilometres south and north of it. Including InSAR results in the inversion requires locking to vary both along dip and along strike. 3-D spatially variable locking models show that shallow creep occurs along the central 20-km-long segment. North and south of the central segment, the interseismic coupling is less resolved, and data still allows significant slip deficit to accumulate. Using the interseismic moment deficit buildup resulting from our inversions and the seismicity rate, we estimate recurrence time for magnitude 6.5 + earthquake to be between 200 and 1200 yr. Finally, PS-InSAR time-series identify a 2 cm transient deformation that occurred on a secondary thrust, east of the main Quito fault between 1995 and 1997. [ABSTRACT FROM AUTHOR]

Published

2020