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The economic costs of extreme weather events: a hydrometeorological CGE analysis for Malawi

Published online by Cambridge University Press:  10 January 2011

KARL PAUW ,
JAMES THURLOW ,
MURTHY BACHU  and
DIRK ERNST VAN SEVENTER
KARL PAUW
Affiliation:
International Food Policy Research Institute, PO Box 31666, Lilongwe 3, Malawi. Tel: +265-1-789747. Email: k.pauw@cgiar.org
JAMES THURLOW
Affiliation:
United Nations University World Institute for Development Economics Research, Helsinki, Finland, and International Food Policy Research Institute, Washington D.C., USA
MURTHY BACHU
Affiliation:
Risk and Insurance Division, RMSI Private Limited, New Delhi, India
DIRK ERNST VAN SEVENTER
Affiliation:
Trade and Industrial Policy Strategies, Pretoria, South Africa
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Abstract

Extreme weather events such as droughts and floods have potentially damaging implications for developing countries. Previous studies have estimated economic losses during hypothetical or single historical events, and have relied on historical production data rather than explicitly modeling climate. However, effective mitigation strategies require knowledge of the full distribution of weather events and their isolated effects on economic outcomes. We combine stochastic hydrometeorological crop-loss models with a regionalized computable general equilibrium model to estimate losses for the full distribution of possible weather events in Malawi. Results indicate that, based on repeated sampling from historical events, at least 1.7 per cent of Malawi's gross domestic product (GDP) is lost each year due to the combined effects of droughts and floods. Smaller-scale farmers in the southern region of the country are worst affected. However, poverty among urban and nonfarm households also increases due to national food shortages and higher domestic prices.

Type
Research Article
Information
Environment and Development Economics , Volume 16 , Issue 2 , April 2011 , pp. 177 - 198
Copyright
Copyright © Cambridge University Press 2011

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References

Agnew, C.T. (2000), ‘Using the SPI to identify drought’, Drought 12 (1): 612.Google Scholar
Arndt, C. and Bacou, M. (2000), ‘Economy-wide effects of climate variability and climate prediction in Mozambique’, American Journal of Agricultural Economics 82 (3): 750754.CrossRefGoogle Scholar
Benin, S., Thurlow, J., Diao, X., McCool, C., and Simtowe, F. (2008), ‘Agricultural growth and investment options for poverty reduction in malawi’, Discussion Paper 794, International Food Policy Research Institute, Washington, D.C.Google Scholar
Boyd, R. and Ibarrarán, M.E. (2008), ‘Extreme climate events and adaptation: an exploratory analysis of drought in Mexico’, Environment and Development Economics 14: 371395.CrossRefGoogle Scholar
Cochrane, H. (2004), ‘Economic loss: myth and measurement’, Disaster Prevention and Management 13 (4): 290296.Google Scholar
Denning, G., Kabambe, P., Sanchez, P., Malik, A., Flor, R., Harawa, R., Nkhoma, P., Zamba, C., Banda, C., Magombo, C., Keating, M., Wangila, J. and Sachs, J. (2009), ‘Input subsidies to improve smallholder maize productivity in Malawi: toward an African Green Revolution’, PLoS Biology 7 (1): 210.CrossRefGoogle ScholarPubMed
Devereux, S. (2007), ‘The impact of droughts and floods on food security and policy options to alleviate negative effects’, Agricultural Economics 37 (s1): 4758.Google Scholar
Dimaranan, B. (ed.) (2006), Global Trade, Assistance, and Production: the GTAP 6 Data Base, Purdue, Indiana: Center for Global Trade Analysis.Google Scholar
FAO (2009), FAOSTAT, Food and Agriculture Organization of the United Nations, Available at: http://faostat.fao.org.Google Scholar
Freeman, P., Martin, L., Mechler, R. and Warner, K (2004), ‘A methodology for incorporating natural catastrophes into macroeconomic projections’, Disaster Prevention and Management 13 (4): 337342.CrossRefGoogle Scholar
Heim, R.R. (2002), ‘A Review of twentieth century drought indices used in the United States’, American Meteorological Society 83: 11491165.CrossRefGoogle Scholar
Horridge, M., Maddan, J. and Wittwer, G. (2005), ‘The impact of the 2002–2003 drought on Australia’, Journal of Policy Modeling 27: 285308.CrossRefGoogle Scholar
Löfgren, H., Robinson, S., and Harris, R. (2001), A Standard Computable General Equilibrium (CGE) model in GAMS, Washington, DC: International Food Policy Research Institute.Google Scholar
McKee, T.B., Doesken, N.J. and Kleist, J. (1993), ‘The relationship of drought frequency and duration to time scales’, Proceedings of the 8th Conference of Applied Climatology, 17–22 January 1993, Anaheim, CA.Google Scholar
MOAFS (2007), Agricultural Production Statistics, Malawi: Ministry of Agriculture and Food Security.Google Scholar
Narayan, P.K. (2003), ‘Macroeconomic impact of natural disasters on a small island economy: evidence from a CGE model’, Applied Economics Letters 10: 721723.CrossRefGoogle Scholar
NSO (2005), Integrated Household Survey 2004/05, Malawi: National Statistical Office.Google Scholar
Rose, A. (2004a), ‘Defining and measuring resilience to disasters’, Disaster Prevention and Management 13 (4): 307314.Google Scholar
Rose, A. (2004b), ‘Economic principles, issues and research priorities in hazard loss estimation’, in Okuyama, Y. and Chang, S. E. (eds), Modeling the Spatial and Economic Effects of Disasters, New York: Springer, pp. 1336.CrossRefGoogle Scholar
Salinger, M.J. (2005), ‘Climate variability and change: past, present and future - an overview’, Climatic Change 70: 929.Google Scholar
Van Der Veen, A. (2004), ‘Disasters and economic damage: macro, meso and micro approaches’, Disaster Prevention and Management 13 (4): 274279.Google Scholar
World Bank (2008), World Development Indicators, Washington, DC: World Bank, Available at http://go.worldbank.org/U0FSM7AQ40.Google Scholar