Abstract
The first regional seismic landslide hazard assessment for Northeastern Mexico is presented. Regional maps predicting the expected areal limits for potential earthquake-induced landslides in terms of coseismic displacements for the 2010 San Pedro earthquake (M 4.0) and two postulated M 5.5 and M 6.5 scenario earthquakes are shown. Permanent displacements were obtained from a global empirical regression based on a critical acceleration ratio (ac/PGA) estimation. Results for the M 4.0 San Pedro event show low cumulative displacements concentrated around the epicentral zone. For this event, occurrence of a few small landslides as disrupted slides and falls were likely. For M 5.5 and M 6.5 scenarios the coseismic displacements depict a high potential for widespread and complex slope failures mainly in the Sierra Madre Oriental hilly areas, although foothills inside the Monterrey Metropolitan Area would be affected. The worst scenario we have postulated is a M 6.5 earthquake during the hurricane season. Hypothetical full-saturated and strong seismic shaking conditions would trigger several rock and soil avalanches as well as other complex landslides. Related damage for this event would be very catastrophic to civil infrastructure and substantial injuries and loss of life are expected mainly in the southwestern portion of the Monterrey Metropolitan Area. Results constitute a useful tool in order to mitigate potential earthquake-induced damage related to regional slope failures.
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References
Ambraseys NN, Menu JM (1988) Earthquake-induced ground displacements. Earthq Eng Struct Dyn 16:985–1006
Bird JF, Bommer J (2004) Earthquake losses due to ground failure. Eng Geol 75:147–179
Bommer JJ, Rodríguez CE (2002) Earthquake-induced landslides in central America. Eng Geol 63:189–220
Caine N (1980) The rainfall intensity-duration control of shallow landslides and debris flows. Geogr Ann A 62:23–27
Capolongo D, Refie A, Mankelow J (2002) Evaluating earthquake-triggered landslide hazard at the basin scale through GIS in the upper Sele River. Surv Geophys 23(6):595–625
Chapa Guerrero JR (1994) Estabilidad de taludes escarpados, Sierra Madre Oriental, N.L., México. Zbl Geol Paläont Teil I: 1019–1026
Chávez-Cabello G, Aranda-Gómez JJ, Molina-Garza RS, Cossío-Torres T, Arvizu-Gutiérrez IR, González-Naranjo GA (2005) La falla San Marcos: una estructura jurásica de basamento multirreactivada del noreste de México. Bol Soc Geol Mex 57(1):27–52
Chousianitis K, Del Gaudio V, Kalogeras I, Ganas A (2014) Predictive model of Arias intensity and Newmark displacement for regional scale evaluation of earthquake-induced landslide hazard in Greece. Soil Dyn Earthq Eng 65:11–29
Doser DI (1987) The 16 August 1931 valentine, Texas, earthquake: evidence for normal faulting in west Texas. Bull Seismol Soc Am 77:2005–2017
Doser DI, Rodríguez J (1993) The seismicity of Chihuahua, Mexico, and the 1928 Parral earthquake. Phys Earth Planet Inter 78:97–104
Du W, Wang G (2016) A one-step Newmark displacement model for probabilistic seismic slope displacement hazard analysis. Eng Geol 205:12–33
Eguiluz de Antuñano S, Aranda García M, Marret R (2000) Tectónica de la Sierra Madre Oriental. Bol Soc Geol Mex 53:1–26
Frohlich C, Davis SD (2002) Texas earthquakes. First edition. Springer, University of Texas Press, Austin, pp 277
Galván-Ramírez IN, Montalvo-Arrieta J (2008) The historical seismicity and prediction of ground motion in northeast Mexico. J S Am Earth Sci 25:37–48
García Acosta V, Suárez Reinoso G (1996) Los sismos en la historia de México. Universidad Nacional Autónoma de México, México
Gómez-Arredondo CM, Montalvo-Arrieta J, Iglesias-Mendoza A, Espindola-Castro V (2016) Relocation and seismotectonic interpretation of the seismic swarm of August-December of 2012 in the Linares area, northeastern Mexico. Geofis Int 55(2):95–106
González de Vallejo LI, Ferrer M, Ortuño L, Oteo C (2002) Ingeniería geológica. Pearson Educación, Madrid, p 744
Guzzetti F, Peruccacci S, Rossi M, Stark C (2008) The rainfall intensity-duration control of shallow landslides and debris flows: an update. Landslides 5:3–17
Higuera-Díaz IC, Fischer MP, Wilkerson MS (2005) Geometry and kinematics of the nuncios detachment fold complex: implications for lithotectonics in northeastern Mexico. Tectonics 24:1–19
Hsieh SY, Lee CT (2011) Empirical estimation of Newmark displacement from the Arias intensity and critical acceleration. Eng Geol 122:34–42
Jaimes MA, Niño M, Reinoso E (2013) Una aproximación para la obtención de mapas de desplazamiento traslacional de laderas a nivel regional inducidos por sismos. Rev Ing Sism 89:1–23
Jibson RW (1993) Predicting earthquake-induced landslide displacements using Newmark’s sliding block analysis. Transp Res Rec 1411:9–17
Jibson RW, Keefer DK (1993) Analysis of the seismic origin of landslides: examples from the New Madrid seismic zone. Geol Soc Am Bull 105:521–536
Jibson RW, Harp E, Michael A (2000) A method for producing digital probabilistic seismic landslide hazard maps. Eng Geol 58:271–289
Jibson RW (2007) Regression models for estimating coseismic landslide displacement. Eng Geol 91:209–218
Keefer DK (1984) Landslides caused by earthquakes. Geol Soc Am Bull 95:406–421
Liu J, Shi J, Wang T, Wu S (2017) Seismic landslide hazard assessment in the Tianshui area, China, based on scenario earthquakes. Bull Eng Geol Environ. doi:10.1007/s10064-016-0998-8
Mazzotti S (2007) Geodynamic models for earthquake studies in intraplate North America. In Stein S, Mazzotti S (eds) Continental intraplate earthquakes: Science, hazard, and policy issues. Geological Society of America Special Paper 425:17–33
Montalvo-Arrieta JC, Cavazos-Tovar P, Navarro de León I, Alva-Niño E, Medina-Barrera F (2008) Mapping seismic site classes in Monterrey Metropolitan area, northeast Mexico. Bol Soc Geol Mex 60(2):147–157
Montalvo-Arrieta JC, Chávez-Cabello G, Velasco-Tapia F, Navarro de León I (2009) Causes and effects of landslides in the Monterrey Metropolitan area, NE Mexico. In: Werner D, Friedman H (eds) Landslides: causes, types and effects. Nova, New York, pp 1–32
Montalvo-Arrieta JC, Ramos-Zuñiga LG, Navarro de León I, Ramírez-Fernández JA (2011) Una aproximación a la regionalización sísmica del estado de Nuevo León, basada en velocidades de propagación de ondas de corte y geología. Bol Soc Geol Mex 63(2):217–233
Montalvo-Arrieta JC, Sosa-Ramírez RL, Paz-Martínez EG (2015) Relationship between MMI data and ground shakingin the state of Nuevo León, northeastern Mexico. Seismol Res Lett 86(5):1–7
Montalvo-Arrieta JC, Sosa-Ramírez RL, Pérez-Campos X (2017) Evaluation of macroseismic intensities in Mexico from recent earthquakes using ¿Sintió un sismo? (did you feel it?). Geofis Int 56(1):27–36
Natali SG, Sbar ML (1982) Seismicity in the epicentral region of the 1887 northeastern Sonora earthquake, Mexico. Bull Seismol Soc Am 72:181–196
Newmark NM (1965) Effects of earthquakes on dams and embankments. Geotechnique 15:139–160
Padilla y Sánchez RJ (1985) Las estructuras de la Curvatura de Monterrey, Estados de Coahuila, Nuevo León, Zacatecas y San Luis Potosi. Rev Inst Geol 6:1–20
Pankow KL, Pechmann JC (2004) The SEA99 ground-motion predictive relations for extensional tectonic regimes: revisions and a new peak ground velocity relation. Bull Seismol Soc Am 94:341–348
Ramos-Zuñiga LG, Montalvo-Arrieta JC, Pérez-Campos X, Váldes-González C (2012a) Seismic characterization of station LNIG as a reference site in northeast Mexico. Geofis Int 51:185–195
Ramos-Zuñiga LG, Medina-Ferrusquía H, Montalvo-Arrieta J (2012b) Patrones de sismicidad en la curvatura de Monterrey, noreste de México. Rev Mex Cienc Geol 29(2):572–589
Ramos Zuñiga LG (2017) Estudio sismotectónico en el NE de México e implicaciones de riesgo sísmico para el área metropolitana de Monterrey, N.L. PhD Thesis. Universidad Autónoma de Nuevo León. In progress
Rodríguez CE, Boomer J, Chandler R (1999) Earthquake-induced landslides: 1980-1997. Soil Dyn Earthq Eng 18:325–346
Salinas-Jasso JA, Montalvo-Arrieta JC, Alva-Niño E, Navarro de León I, Gómez-González JM (2017a) Seismic site effects in the central zone of Monterrey Metropolitan area (Northeast Mexico) from a geotechnical-multidisciplanary assessment. Bull Eng Geol Environ. In press. doi:10.1007/s10064-017-1065-9
Salinas-Jasso JA, Montalvo-Arrieta JC, Reinoso-Angulo E (2017b) Landslides induced by a low seismic sequence at continental interiors. Case of study: The Santa Rosa canyon, Northeastern Mexico. Landslides. In review
Salinas-Jasso JA, Salinas-Jasso RA, Montalvo-Arrieta JC, Alva-Niño E (2017c) Inventario de movimientos en masa en el Sector Sur de la Saliente de Monterrey. Caso de estudio: Cañón Santa Rosa, Nuevo León (Noreste de México). Rev Mex Cienc Geol. In review
Saygili G, Rathje EM (2008) Empirical predictive models for earthquake-induced sliding displacements of slopes. J Geotech Geoenviron 134(6):790–803
Scholz CH, Avilés C, Wesnousky S (1986) Scaling differences between large interplate and intraplate earthquakes. Bull Seismol Soc Am 76:65–70
Spudich P, Joyner WB, Lindh AG, Boore DM, Margaris BM, Fletcher JB (1999) SEA99: a revised ground motion prediction relation for use in extensional tectonic regimes. Bull Seismol Soc Am 89:1156–1170
Toro GR, Abrahamson N, Schneider J (1997) Model of strong ground motions from earthquakes in central and eastern NorthAmerica: best estimates and uncertainties. Seismol Res Lett 68:41–57
Wells DL, Coppersmith KJ (1994) New empirical relationships among magnitude, rupture length, rupture width, rupture area, and surface displacement. Bull Seismol Soc Am 84(4):974–1002
Wieczorek GF, Wilson RC, Harp EL (1985) Map showing slope stability during earthquakes in San Mateo County California. USGS Misc Investig Map Scale 1:62500
Widmann BL, Kirkham RM, Rogers WP (1998) Preliminary Quaternary fault and fold map and database of Colorado. Colorado Geological Survey Open File Report 98(8)
Wilson RC, Keefer DK (1983) Dynamic analysis of a slope failure from the 6 August 1979 coyote Lake, California, earthquake. Bull Seismol Soc Am 73:863–877
Wilson RC, Keefer DK (1985) Predicting areal limits of earthquake-induced landsliding. In: Ziony JI (ed) Evaluating earthquake hazards in the Los Angeles region—an earth-science perspective. U.S. Geol Surv Prof Pap 1360:317–345
Xie J (1998) Spectral inversion of Lg from earthquakes: a modified method with applications to the 1995, western Texas earthquake sequence. Bull Seismol Soc Am 88:1525–1537
Acknowledgements
We are grateful to Martin Gordon Culshaw and the two anonymous reviewers for their critical remarks that helped to greatly improve the original manuscript. JAS-J and LGR-Z received a scholarship from Consejo Nacional de Ciencia y Tecnología (CONACYT).
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Salinas-Jasso, J.A., Ramos-Zuñiga, L.G. & Montalvo-Arrieta, J.C. Regional landslide hazard assessment from seismically induced displacements in Monterrey Metropolitan area, Northeastern Mexico. Bull Eng Geol Environ 78, 1127–1141 (2019). https://doi.org/10.1007/s10064-017-1087-3
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DOI: https://doi.org/10.1007/s10064-017-1087-3