Abstract
This article describes the landslide risk assessment of the Rampac Grande rural community in the Peruvian Andes, where an unexpectedly fast-moving landslide claimed fatalities in 2009. The study site represents a socially, culturally, and geologically challenging environment that limits applicable technical solutions for landslide risk reduction and demands a high level of community participation in all risk reduction steps. The performed landslide surface movement monitoring and slope stability calculations showed that the studied slopes are very close to failure. Therefore, the detailed hazard assessment was combined with field investigations of household vulnerabilities to perform a qualitative risk assessment in the zone around the 2009 catastrophic landslide. Results show that the high vulnerability, rather than the very high hazard, is responsible for assigning houses to the high-risk classes and education or improvement of the households’ income is key for further risk reduction. This underlines the importance of vulnerability reduction through the collaboration of the community members with external actors (e.g., Peruvian experts), which was interrupted by the COVID-19 pandemic restrictions. The context of the performed landslide risk assessment provides a summary of the 12-year-long involvement of different actors in the landslide risk reduction effort and the evaluation of the effectiveness of the previously adopted mitigation measures. It suggests that the community perspective on the mitigation measures and its risk perception changes determine the long-term risk reduction outcomes.
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Bommer JJ, Rolo R, Mitroulia A, Berdousi P (2002) Geotechnical properties and seismic slope stability of volcanic soils. 12th European conference on earthquake engineering, 9–13 September 2002, London, United Kingdom, Paper Reference 695
CENEPRED (2014) Manual for the evaluation of risks caused by natural phenomena (in Spanish). CENEPRED, Lima
Chandler RJ (1984) Recent European experience of landslides in over-consolidated clays and soft rocks (State-of-the-Art Lecture). In: Proceedings of 4th international symposium on landslides Toronto, vol 1, pp 61–81
Corominas J (1996) The angle of reach as a mobility index for small and large landslides. Can Geotech J 33(2):260–271. https://doi.org/10.1139/t96-005
Davila C, Vera R, Pacheco L, Duran G (2020) Evaluation of the geotechnical behavior of a volcanic soil wall with additions of lime and cement against landslides. IOP Conf Ser Mater Sci Eng 758:012083. https://doi.org/10.1088/1757-899X/758/1/012083
Evans SG, Bishop NF, Fidel Smoll L, Valderrama Murillo P, Delaney KB, Oliver-Smith A (2009) A re-examination of the mechanism and human impact of catastrophic mass flows originating on Nevado Huascarán, Cordillera Blanca, Peru in 1962 and 1970. Eng Geol 108:96–118
Federico A, Popescu M, Elia G, Fidelibus C, Interno G, Murianni A (2012) Prediction of time to slope failure: a general framework. Environ Earth Sci 66:245–256. https://doi.org/10.1007/s12665-011-1231-5ns
Figueiredo AR, Simões JC, Menegat R, Strauss S, Rodrigues BB (2019) Perceptions of and adaptation to climate change in the Cordillera Blanca, Peru. https://doi.org/10.14393/SN-v31-2019-45623
FOEN (2016) Protection against Mass Movement Hazards. Guideline for the integrated hazard management of landslides, rockfall and hillslope debris flows. Federal Office for the Environment, Bern. The environment in practice no. 1608
Froude MJ, Petley DN (2018) Global fatal landslide occurrence from 2004 to 2016. Nat Hazards Earth Syst Sci 18:2161–2181. https://doi.org/10.5194/nhess-18-2161-2018
Geocon (2015) Instruction manual Model 1610 Tape Extensometer. Geocon
Guillard-Gonçalves C, Zêzere JL (2018) Combining social vulnerability and physical vulnerability to analyse landslide risk at the municipal scale. Geosciences 8:294. https://doi.org/10.3390/geosciences8080294
Haller A (2010) Yungay: recent tendencies and spatial perceptions in an Andean risk zone. Espacio y Desarrollo 22:65–75
Heras H, Tavera H (2002) Localzación de áreas probables a ser afectadas por grandes sismos en el borde oeste de Perú: estimación a partir de períodos de retorno local basado en la distribución de valores de “b.” Bol Soc Geológica Perú 93:7–16
Hostettler S, Jöhr A, Montes C, D’Acunzi A (2019) Community-based landslide risk reduction: a review of a Red Cross soil bioengineering for resilience program in Honduras. Landslides 16:1779–1791. https://doi.org/10.1007/s10346-019-01161-3
Huggel C, Wallimann-Helmer I, Stone F, Wolfgang C (2016) Reconciling justice and attribution research to advance climate policy. Nat Clim Change. https://doi.org/10.1038/NCLIMATE3104
Huggel C, Cochachin A, Drenkhan F, Fluixá-Sanmartín J, Frey H, García Hernández J, Jurt C, Muñoz R, Price K, Vicuña L (2020) Glacier Lake 513, Peru: lessons for early warning service development. WMO Bull 69(1):45–52
INGEMMET (1995) Carta Geologica del Peru, 19-h Carhuaz, M 1:100,000. INGEMMET, Lima
Jibson RW (2012) Models of triggering of landslides during earthquakes. In: Clague JJ, Stead D (eds) Landslides: types, mechanisms and modeling. Cambridge University Press, Cambridge, pp 196–206
Kaser G, Ames A, Zamora M (1990) Glacier fluctuations and climate in the Cordillera Blanca, Perú. Ann Glaciol 14:136–140
Klimeš J (2018) Extensometer. In: Bobrowsky PT, Marker B (eds) Encyclopedia of engineering geology. Encyclopedia of earth sciences series. Springer, Cham, pp 323–324
Klimeš J, Vilímek V (2011) A catastrophic landslide near Rampac Grande in the Cordillera Negra, northern Peru. Landslides 8:309–320
Klimeš J, Novotný J, Rapre AC, Balek J, Zahradníček P, Strozzi T, Sana H, Frey H, René M, Štěpánek M, Meitner J, Junghardt J (2021) Paraglacial rock slope stability under changing environmental conditions Safuna Lakes, Cordillera Blanca Peru. Front Earth Sci. https://doi.org/10.3389/feart.2021.607277
Klimeš J, Rosario AM, Vargas R, Raška P, Vicuña L, Jurt C (2019) Community participation in landslide risk reduction: a case history from Central Andes, Peru. Landslides 16:1763–1777
Košťák B, Vilímek V, Zapata ML (2002) Registration of microdisplacements at a Cordillera Blanca fault scarp. Acta Montana IRSM AS CR 19:61–74
Macharé J, Fenton CH, Machette MN, Lavenu A, Costa C, Dart RL (2003) Database and map of Quaternary faults and folds in Perú and its offshore region. Open File Report 03-451, USGS
Maes J, Mertens K, Jacobs L et al (2018) Social multi-criteria evaluation to identify appropriate disaster risk reduction measures: application to landslides in the Rwenzori Mountains, Uganda. Landslides. https://doi.org/10.1007/s10346-018-1030-0
Maskrey A (1989) Disaster mitigation: a community based approach (development guidelines). Oxfam, Oxford
Mercer J, Kelman I, Suchet-pearson S, Lloyd K (2009) Integrating indigenous and scientific knowledge bases for disaster risk reduction in Papua New Guinea. Geogr Ann Ser B Hum Geog 91(2):157–183. https://doi.org/10.1111/j.1468-0467.2009.00312.x
Miranda E (2019) Lagunas Peru May 26, 2019 Earthquake, Virtual Assessment Structural Team report. NHERI DesignSafe Project ID: PRJ-2395, pp 103
Muñoz AR, Gonzales C, Price K, Rosario A, Huggel C, Frey H, García J, Cochachin A, Portocarrero C, Mesa L (2016) Managing glacier related risks disaster in the Chucchún catchment, Cordillera Blanca, Peru. In: Salzmann N, Huggel C, Nussbaumer S, Ziervogel G (eds) Climate change adaptation strategies—an upstream-downstream perspective. Springer, Cham, pp 59–78. https://doi.org/10.1007/978-3-319-40773-9_4
Nadim F, Jaedicke C, Smebye H, Kalsnes B (2013) Assessment of global landslide hazard hotspots. In: Sassa K, Rouhban B, Briceño S, McSaveney M, He B (eds) Landslides: global risk preparedness. Springer, Berlin. https://doi.org/10.1007/978-3-642-22087-6_4
Neal DM (1997) Reconsidering the phases of disaster. Int J Mass Emerg Disasters 15:239–264
Novotný J (2014) Engineering geological models—some examples of use for landslide assessments, 12th IAEG Congress Torino 2014. In: Lollino G et al. (eds) Engineering geology for society and territory, vol 7. Springer International Publishing, Switzerland, pp 11–15. https://doi.org/10.1007/978-3-319-09303-1_2
Parry S, Baynes F, Novotný J (2018) Conceptual engineering geological models. In: Shakoor A, Kato K (eds) IAEG/AEG annual meeting proceedings. Springer, San Francisco. https://doi.org/10.1007/978-3-319-93142-5
Pedoth L, Taylor R, Kofler C, Stawinoga AE, Forrester J, Matin N, Schneiderbauer S (2019) The role of risk perception and community networks in preparing for and responding to landslides, a dolomite case study. In: Deeming H, Fordham M, Kuhlicke C, Pedoth L, Schneiderbauer S, Shreve C (eds) Framing community disaster resilience: resources, capacities, learning, and action. Wiley, New York, pp 197–219
Pirone M, Papa R, Nicotera MV, Urciuoli G (2015) Soil water balance in an unsaturated pyroclastic slope for evaluation of soil hydraulic behaviour and boundary conditions. J Hydrol 528:63–83. https://doi.org/10.1016/j.jhydrol.2015.06.005
Plafker G, Ericksen GE, Concha JF (1971) Geological aspects of the May 31, 1970, Peru earthquake. Bull Seismol Soc Am 61:543–578
Raetzo H, Lateltin O, Bollinger D, Tripet JP (2002) Hazard assessment in Switzerland—codes of practice for mass movements. Bull Eng Geol Environ 61:263–268. https://doi.org/10.1007/s10064-002-0163-4
Rechberger C, Fey C, Zangerl C (2021) Structural characterisation, internal deformation, and kinematics of an active deep-seated rock slide in a valley glacier retreat area. Eng Geol 286:106048
Roháč J (2021) Experimental investigation of shear strength of soils from the Dobkovičky landslide area and development of correlations between soil strength and their physical properties, Ph.D. Thesis, Charles University, Faculty of Science
Roháč J, Scaringi G, Boháč J, Kycl P, Najser J (2020) Revisiting strength concepts and correlations with soil index properties: insights from the Dobkovičky landslide in Czech Republic. Landslides 17:597–614
Rotisciani GM, Desideri A, Amorosi A (2021) Unsaturated structured soils: constitutive modelling and stability analyses. Acta Geotech 16:3355–3380. https://doi.org/10.1007/s11440-021-01313-7
Sassa K (2015) ISDR-ICL Sendai partnerships 2015–2025 for global promotion of understanding and reducing landslide disaster risk. Landslides 12:631–640. https://doi.org/10.1007/s10346-015-0586-1
Scheidegger A (1973) On the prediction of the reach and velocity of catastrophic landslides. Rock Mech 5:231–236
Skempton AW (1985) Residual strength of clays in landslides, folded strata and the laboratory. Géotechnique 35:3–18
Stemberk J, Vilímek V, Klimeš J, Blahůt J, Hartvich F, Balek J (2017) Landslide hazard and risk management (WCoE 2014–2017). In: Sassa K, Mikoš M, Yin Y (eds) Advancing culture of living with landslides. WLF 2017. Springer, Cham, pp 373–377. https://doi.org/10.1007/978-3-319-59469-9_32
Strozzi T, Klimeš J, Frey H, Caduff R, Huggel C, Wegmüller U, Rapre AC (2018) Satellite SAR interferometry for the improved assessment of the state of activity of landslides: a case study from the Cordilleras of Peru. Remot Sens Env 217:111–125. https://doi.org/10.1016/j.rse.2018.08.014
Thywissen K (2006) Components of risk: a comparative glossary. UNU-EHS, Bonn, Germany
USGS, Earthquake Hazard Program (2020a) https://earthquake.usgs.gov/earthquakes/eventpage/iscgem796163/shakemap/pga. Accessed 27 Aug 2021
USGS, Earthquake Hazard Program (2020b) https://earthquake.usgs.gov/earthquakes/eventpage/us60003sc0/executive. Accessed 27 Aug 2021
Vilímek V, Klimeš J, Torres MZ (2016) Reassessment of the development and hazard of the Rampac Grande landslide, Cordillera Negra, Peru. Geoenviron Disasters 3:5. https://doi.org/10.1186/s40677-016-0039-8
Vilímek V, Klimeš J, Tito Mamani RV, Bastante AJ, Astete FV, Champi PZM (2020) Contribution of the collaborative effort of the Czech WCoE to landslide risk reduction at the Machupicchu World Heritage Site, Peru. Landslides 17:2683–2688. https://doi.org/10.1007/s10346-020-01509-0
Vilímek V, Klimeš J, Stemberk J, Burda J, Kycl P, Blahůt J (2021) Complex geomorphological and engineering geological research of landslides with adverse societal impacts. In: Sassa K, Mikoš M, Sassa S, Bobrowsky PT, Takara K, Dang K (eds) Understanding and reducing landslide disaster risk. WLF 2020. ICL Contribution to Landslide Disaster Risk Reduction. Volume 1: Sendai Partnerships and Kyoto Landslide Commitment. Springer, Cham, 275–280. https://doi.org/10.1007/978-3-030-60196-6_20
Weston R (2008) Preliminary summary of the Pallcamachay Property, Ancash, Peru. Report Strait Gold Corp. Accessed 29 Apr 2010
Yoshikawa K, Úbeda J, Masías P, Pari W, Apaza F, Vasquez P, Ccallata B, Concha R, Luna G, Iparraguirre J, Ramos I, De la Cruz R, Pellitero R, Bonshoms M (2020) Current thermal state of permafrost in the southern Peruvian Andes and potential impact from El Niño–Southern Oscillation (ENSO). Permafrost Periglac Process. https://doi.org/10.1002/ppp.2064
Acknowledgements
We would like to thank Dr. Mariana Pirone (University of Naples Federico II, Italy) and Dr. Bohuslav Kuřík (Charles University Prague, Czech Republic) for discussions on slope stability and anthropological aspects of the research. We also acknowledge the ongoing support of our research activities by the Czech Embassy in Lima, Peru. The research works were supported by the long-term conceptual development research organization (RVO: 67985891) project and by the Strategic Research Plan of the Czech Geological Survey (DKRVO/ČGS 2023-2027, topic 6).
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The preparation of the manuscript was not directly supported by any specific grant proposal. Funding used to perform field work is acknowledged in the Acknowledgement section and it includes especially internal institutional funding.
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Manuscript conceptualization JK and JN; methodology JK, JN, JB, AMR, ER-M, AC, YO, RV; investigation JK, JN, JB, AMR, JCT, RV, DL, ER-M, AC, YO, HJ, HV, EM; writing—review and editing JK, JN, JB, AMR, RV, figure and table preparation JK, JN, JB. All authors reviewed the manuscript.
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Klimeš, J., Novotný, J., Balek, J. et al. Landslide hazard assessment and risk reduction in the rural community of Rampac Grande, Cordillera Negra, Peru. Environ Earth Sci 83, 27 (2024). https://doi.org/10.1007/s12665-023-11307-1
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DOI: https://doi.org/10.1007/s12665-023-11307-1