Geophysical Study and 3-D Modeling of Site Effects in Viña del Mar,Chile

Abstract

The Maule 2010 earthquake (Mw 8.8) produced damage to several buildings throughout Central Chile. This was particularly the case in downtown Viña del Mar, where an anomalous concentration of structural damage was found in several medium-rise buildings distributed along a narrow area approximately 1 km in length. These observations suggest the possibility of a localized area of seismic amplification effects. We conducted a geophysical characterization using surface wave–based techniques and gravimetry to characterize the main dynamic properties of the soil and the depth of the basin. These data, complemented with several standard penetration test measurements, were used to develop a three-dimensional (3-D) geotechnical characterization of the area. Additionally, the cyclic behavior of predominant materials was experimentally characterized based on remolded samples. To assess complex site-amplification effects, we developed a computational 3-D model constrained by surface-wave geophysics and laboratory results, assuming a homogenous basin infill with increasing stiffness with depth. The results partially agree with damage observations and suggest an explanation related to basement shape in some areas of the modeled region.

Get full access to this article

View all access options for this article.

References

Abraham

J. R.

, Smerzini

, Paolucci

, and Lai

C. G.

, 2016. Numerical study on basin-edge effects in the seismic response of the Gubbio valley, Central Italy, Bulletin of Earthquake Engineering 14, 1437–1459.

Aki

, 1957. Space and time spectra of stationary stochastic waves, with special reference to microtremors, Bulletin of Earthquake Research Institute 35, 415–456.

Antonietti

P. F.

, Mazzieri

, Quarteroni

, and Rapetti

, 2012. Non-conforming high order approximations of the elastodynamics equation, Computer Methods in Applied Mechanics and Engineering 209–212, 212–238.

Arias

, 1970. A measure of earthquake intensity, in Seismic Designfor Nuclear Power Plants ( Hansen

R. J.

, ed.), MIT Press, Cambridge, MA, 438–483.

Becerra

, Podestá

, Monetta

, Sáez

, Leyton

, and Yañez

, 2015. Seismic micro-zoning of Arica and Iquique, Chile, Natural Hazards 79, 567–586.

Bielak

, Graves

R. W.

, Olsen

K. B.

, Taborda

, Ramírez-Guzmán

, Day

S. M.

, Ely

G. P.

, Roten

, Jordan

T. H.

, Maechling

P. J.

, Urbanic

, Cui

, and Juve

, 2010. The ShakeOut earthquake scenario: Verification of three simulation sets, Geophysical Journal International 180, 375–404.

Carrasco

, and Núñez

, 2013. Microzonificación Sísmica de la Ciudad de Viña del Mar, Tesis para optar al grado de Magister en Cienicas, Universidad Técnica Federico Santa María, Valparaíso, Chile.

Chaljub

, Moczo

, Tsuno

, Bard

P. -Y.

, Kristek

, Käser

, Stupazzini

, and Kristekova

, 2010. Quantitative comparison of four numerical predictions of 3D ground motion in the Grenoble valley, France, Bulletin of the Seismological Society of America 100, 1427–1455

Chávez-García

, and Cuenca

, 1998. Site effects and microzonation in Acapulco, Earthquake Spectra 14, 75–93.

10.

Cubrinovski

, and Ishihara

, 1999. Empirical correlation between SPT N-value and relative density for sandy soils, Soils and Foundations 39, 61–71.

11.

Darendeli

M. B.

, 2001. Development of a New Family of Normalized Modulus Reduction and Material Damping Curves, Ph.D. Dissertation, University of Texas at Austin.

12.

Day

S. M.

, Graves

, Bielak

, Dreger

, Larsen

, Olsen

K. B.

, Pitarka

, and Ramirez-Guzman

, 2008. Model for basin effects on long-period response spectra in Southern California. Earthquake Spectra. 24:257–277

13.

Gana

, Wall

, and Gutiérrez

, 1996. Mapa Geológico del Área Valparaíso – Curacaví, Regiones de Valparaíso y Metropolitana, Mapa Geológico Sernageomin No. 1.

14.

Graves

R. W.

, Jordan

T. H.

, Callaghan

, Deelman

, Field

, Juve

, Kesselman

, Maechling

, Mehta

, Milner

, Okaya

, Small

, and Vahi

, 2011. CyberShake: A physics-based seismic hazard model for Southern California, Pure and Applied Geophysics 168, 367–381.

15.

Hayashi

, 2008. Development of the Surface-Wave Methods and Its Application to Site Investigations, Ph.D. Dissertation, Kyoto University, Japan.

16.

Humire

, Sáez

, Leyton

, and Yañez

, 2015. Combining active and passive multi-channel analysis of surface waves to improve reliability of V_S,30 estimation using standard equipment, Bulletin of Earthquake Engineering 13, 1303–1321

17.

Jünemann

, de la Llera

J. C.

, Hube

M. A.

, and Kausel

, 2015. A statistical analysis of reinforced concrete wall buildings damaged during the 2010, Chile earthquake, Engineering Structures 82, 168–185.

18.

Kvaerna

, and Ringdahl

, 1986. Stability of various fk estimation techniques, Norsar Semi-annual Tech Summ 1, 1–86.

19.

Leyton

, Ramírez

, and Vásquez

, 2012. Uso y limitaciones de la Técnica de Nakamura en la clasificación sísmica de suelos, VII Congreso Chileno de Geotecnia.

20.

Leyton

, Ruiz

, Sepúlveda

S. A.

, Contreras

J. P.

, Rebolledo

, and Astroza

, 2013. Microtremors’ HVSR and its correlation with surface geology and damage observed after the 2010 Maule earthquake (Mw 8.8) at Talca and Curicó, Central Chile, Engineering Geology 161, 26–33.

21.

Mazzieri

, Stupazzini

, Guidotti

, and Smerzini

, 2013. SPEED: SPectral Elements in Elastodynamics with Discontinuous Galerkin: A non-conforming approach for 3D multi-scale problems, International Journal for Numerical Methods in Engineering 95, 991–1010.

22.

Montalva

G. A.

, Chávez-Garcia

F. J.

, Tassara

, and Jara Weisser

D. M.

, 2016. Site effects and building damage characterization in Concepción after the M_W 8.8 Maule earthquake, Earthquake Spectra 32, 1469–1488.

23.

Nakamura

, 1989. A method for dynamic characteristics estimation of subsurface using micro-tremor on the ground surface, Quarterly Report of RTRI 30, 25–33.

24.

Roten

, Olsen

K. B.

, and Pechmann

J. C.

, 2012. 3D Simulations of M 7 earthquakes on the Wasatch fault, Utah, part II: Broadband (0–10 Hz) ground motions and nonlinear soil behavior, Bulletin of the Seismological Society of America 102, 2008–2030.

25.

Schnabel

P. B.

, Lysmer

, and Seed

H. B.

, 1972. SHAKE - A Computer Program for Earthquake Response Analysis of Horizontal Layered Sites, Rep. No. EERC 71-12, Earthquake Engineering Research Center, University of California, Berkeley.

26.

Smerzini

, Paolucci

, and Stupazzini

, 2011. Comparison of 3D, 2D and 1D numerical approaches to predict long period earthquake ground motion in the Gubbio plain, Central Italy, Bulletin of Earthquake Engineering 9, 2007–2029.

27.

Thorson

R. M.

, 1999. La Falla Marga-Marga, Viña del Mar – Chile, Universidad Técnica Federico Santa María, Valparaiso, Chile, 42 pp.

28.

Tokimatsu

, 1997. Geotechnical site characterization using surface waves, in Proceedings of 1st International Conference on Earthquake Geotechnical Engineering 3, A. A. Balkema, Rotterdam, the Netherlands, 1333–1368.

29.

Uthayakumar

, 1992. Dynamic properties of sands under cyclic torsional shear, MSc. Thesis, University of British Columbia, Vancouver, Canada.

30.

Wathelet

, 2008. An improved neighborhood algorithm: Parameter conditions and dynamic scaling, Geophysical Research Letters 35, L09301.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.22 MB