Abstract
Landslides pose a serious physical and environmental threat to vulnerable communities living in areas of unplanned housing on steep slopes in the Caribbean. Some of these communities have, in the past, had to be relocated, at costs of millions of dollars, because of major slides triggered by tropical storm rainfall. Even so, evidence shows that: (1) risk reduction is a marginal activity; (2) there has been minimal uptake of hazard maps and vulnerability assessments and (3) there is little on-the-ground delivery of construction for risk reduction. This article directly addresses these issues by developing a low-cost approach to the identification of the potential pore pressure changes that trigger such slides we seek to address these three commentaries directly. A complex 45–60° slope site in St Lucia, West Indies was selected as a pilot for a modelling approach that uses numerical models (FLAC and CHASM) to verify the need for surface water management to effectively reduce landslide risk. Following the model confirmation, a series of drains were designed and constructed at the site. Post-construction evidence indicates the methodology to be sound, in that the site was stable in subsequent 1-in-1 to 1-in-4 year rainfall events. A critical feature of the approach is that it is community-based from data acquisition through to community members participating in construction.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Anderson MG, Holcombe EA (2004) Management of slope stability in communities. Insight 6:15–17
Anderson MG, Holcombe EA (2006a) Purpose driven public sector reform: the need for within-Government capacity build for the management of slope stability in communities (MoSSaiC) in the Caribbean. Environ Manage 37:15–29
Anderson MG, Holcombe EA (2006b) Community based landslide risk reduction. Proceedings Institution Civil Engineers, Engineering Sustainability 159:23–30
Anderson MG, Holcombe EA (2007) Reducing landslide risk in poor housing areas of the Caribbean—developing a new Government–Community partnership model. J Int Dev 19:205–221
Anderson MG, Collison AJC, Hartshorne J, Lloyd DM, Park A (1996) Developments in slope hydrology—stability modelling for tropical slopes. In: Anderson MG, Brooks SM (eds) Advances in hillslope processes. Wiley, Chichester, pp 799–821
Anderson MG, Kemp MJ, Lloyd DM (1997) Hydrological design manual for slope stability in the tropics. Transport Research Laboratory
Anderson MG, Holcombe EA, Renaud J-P (2007) Assessing slope stability in unplanned settlements in developing countries. J Environ Manage 85(1):101–111
Anthony KD (2001) Strengthening modernizing and repositioning the economy. Budget speech by The Honourable Dr. Kenny D. Anthony, Prime Minister and Minister for Finance, Economic Affairs and Information. Government of Saint Lucia
Bishop AW (1955) The use of the slip circle in the stability analysis of slopes. Geotechnique 5(1):7–77
British Standard (1964) Schedule of weights of building materials No. 648
Caribbean Development Bank (2006) Sourcebook on the integration of natural hazards into the environmental impact (EIA) process. NIHA-EIA sourcebook, p 217
Carrara A (1995) GIS technology in mapping landside hazard. In: Carrara A, Guzzetti F (eds) Geographical information systems in assessing natural hazards. Kluwer, Dordrecht, pp 135–176
Carrara A, Guzzetti F, Cardinali M, Reichenbach P (1999) Use of GIS technology in the prediction and monitoring of landslide hazard. Nat Hazards 20:117–135
Charveriat C (2000) Natural disasters in Latin America and the Caribbean: an overview of risk, Working Paper No. 434. Research Department, Inter-American Development Bank, Washington, DC
Collison A (1993) Assessing the influence of vegetation on slope stability in the tropics. Unpublished PhD thesis. University of Bristol
Commonwealth of Dominica (1996) Building code
Dai FC, Lee CF, Ngai YY (2002) Landslide risk assessment and management: an overview. Eng Geol 64:65–87
DFID (2004) Disaster risk reduction: a development concern. DFID, London
Emmanuel N (2000) Landslide vulnerability analysis from the hillslopes around Castries. Unpublished Masters thesis, University of Cambridge, 101 pp
Gay D, Rogers C (1999) Black Mallet landslide: preliminary geotechnical evaluation, 9 pp. http://www.geocities.com/black_mallet/blackmalletuwi.htm
Geotechnical Control Office (1980) Cut slopes in Hong Kong: Assessment of stability by empiricism (CHASE). GEO, Public Works Department, Hong Kong
Glade T, Crozier MJ (2005) A review of scale dependency in landslide hazard and risk analysis. In: Glade T, Anderson MG, Crozier MJ (eds) Landslide hazard and risk. Wiley, Chichester, pp 75–138
Government of St Lucia (2002) PRF and Riviere Mitant, http://stlucia.gov.lc/pr2002/prf_&_riviere_mitant_-_building_bridges.htm
Haque CE, Etkin D (2007) People and community as constituent parts of hazards: the significance of societal dimensions in hazards analysis. Nat Hazards 41(2):271–282
Hencher S, Anderson MG, Martin RP (2006) Hydrogeology of landslides in weathered profiles. International conference on slopes Kuala Lumpur, Malaysia, pp 463–474
Henderson-Sellers A, Zhang H, Berz G, Emanuel K, Gray C, Landsea C, Holland G, Lighthill J, Shieh SL, Webster P, McGuffeie K (1998) Tropical cyclones and global climate change: a post-IPCC assessment. Bull Amer Meteorol Soc 79:19–38
Itasca (2000) FLAC (Fast Lagrangian Analysis of Continua) user’s manuals. Itasca Consulting Group Inc, Minneapolis, USA
Karnawati D, Ibriam I, Anderson MG, Holcombe EA, Mummery GT, Wang Y, Renaud J-P (2005) Identifying slope stability controls in southern slide risk glade T. In: Anderson MG, Crozier M (eds). John Wiley, pp 733–763
Knutson TR, Tuelya RE (1999) Increased hurricane intensities with CO2-induced warming as simulated using the GFDL hurricane prediction system. Clim Dyn 15:503–519
Knutson TR, Tuelya RE (2004) Impact of CO2-induced warming on simulated hurricane intensity and precipitation: sensitivity to the choice of climate model and convective parameterization. J Clim 17:3477–3495
Knutson TR, Tuleya RE, Kurihara Y (1998) Simulated increase of hurricane intensities in a CO2 warmed climate. Science 279:1018–1021
Koo YC, Lumb P (1981) Correlation between rainfall intensities and groundwater levels in the natural slopes of Hong Kong. Hong Kong Eng 1:49–52
Lloyd DM, Anderson MG, Hussein AN, Jamaludin A, Wilkinson Pl (2001) Preventing landslides on roads and railways: a new risk-based approach. Proc Inst Civil Eng 144:129–134
Lumb P (1975) Slope failures in Hong Kong. Q J Eng Geol 8:31–65
Mann EM, Emanual KA (2006) Atlantic hurricane trends linked to climate change. EOS Trans Am Geophys Union 87:233–235
Mechler R (2004) Natural disaster risk management and financing disaster losses in developing countries. Verlag für Versicherungswissenschaft, Karlsruhe
Murphy BL (2007) Locating social capital in resilient community-level emergency management. Nat Hazards 41(2):297–315
OECS (2006) Disaster response and risk reduction programme (unpublished), 12 pp
Opadeyi S, Ali S, Chin F (2005) Status of hazard maps, vulnerability assessments and digital maps in the Caribbean. Caribbean Disaster Emergency response Agency (CEDRA), Final Report, 58 pp
Strata Engineering Consultants Ltd. (1999). Landslide investigation at Black Mallet/Maynard Hill, Castries, St. Lucia, West Indies. Consultants Report to the Government of Saint Lucia. http://www.geocities.com/black_mallet/blackmalletgoslreport.htm
Teams (1999) Position paper on the earth movement crisis of Black Mallet and Maynard Hill, 7 pp
Tompkins EL (2005) Planning for climate change in small islands: insights from national hurricane preparedness in the Cayman Islands, Global Environmental Change A, pp 139–149
UN-ISDR (United Nations International Strategy for Disaster reduction) (2002) Living with risk; a global view of disaster reduction initiatives. UN Inter-Agency Secretariat, Geneva
USGS (2003) National landslide hazards mitigation strategy—a framework for loss reduction circular 1244
van Genuchten MTh (1980) A closed form equation for predicting the hydraulic conductivity of unsaturated soils. Soil Sci Soc Am J 44:892–898
Wamsler C (2006) Mainstreaming risk reduction in urban planning and housing: a challenge for international aid organisations. Disaster 30:151–177
Wamsler C (2007) Bridging the gaps: stakeholder based strategies for risk reduction and financing for the urban poor. Environ Urban 19(1):115–142
Wilkinson PL, Brooks SM, Anderson MG (1998) Investigating the effect of moisture extraction by vegetation upon slope stability: further developments of a Combined Hydrology and Stability Model (CHASM). In: Proceedings of the British Hydrological Society International Symposium on Hydrology in a Changing Environment. Theme 4: Hydrology of environmental hazards, pp 165–178
Wilkinson PL, Brooks SM, Anderson MG (2000) Design and application of an automated non-circular slip surface search within a Combined Hydrology and Stability Model (CHASM). Hydrol Process 14:2003–2017
Wilkinson PW (2001) Investigating the hydrological and geotechnical effects of vegetation on slope stability: development of a fully integrated numerical model. Unpublished PhD thesis. University of Bristol
World Bank Community Based Disaster Risk Management (2007) Environmental Planning Collaborative, Ahmedabad, India and the World Bank Institute. On-line course. http://go.worldbank.org/0A4B712DW0
Wu TH, McKinnell WP, Swanton DN (1979) Strength of tree roots and landslides on Prince of Wales Island, Alaska. Can Geotech J 16:19–33
Xie M, Esaki T, Zhou G (2004) GIS-based probabilistic mapping of landslide hazard using a three-dimensional deterministic model. Nat Hazards 33:265–282
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Anderson, M., Holcombe, L., Flory, R. et al. Implementing low-cost landslide risk reduction: a pilot study in unplanned housing areas of the Caribbean. Nat Hazards 47, 297–315 (2008). https://doi.org/10.1007/s11069-008-9220-z
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11069-008-9220-z