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Cross-sectional analyses of climate change impacts

Author

Listed:
  • Mendelsohn, Robert
  • Dinar, Ariel
  • Basist, Alan
  • Kurukulasuriya, Pradeep
  • Ihsan Ajwad, Mohamed
  • Kogan, Felix
  • Williams, Claude

Abstract

The authors explore the use of cross-sectional analysis to measure the impacts of climate change on agriculture. The impact literature, using experiments on crops in laboratory settings combined with simulation models, suggests that agriculture will be strongly affected by climate change. The extent of these effects varies by country and region. Therefore, local experiments are needed for policy purposes, which becomes expensive and difficult to implement for most developing countries. The cross-sectional technique, as an alternative approach, examines farm performance across a broad range of climates. By seeing how farm performance changes with climate, one can estimate long-run impacts. The advantage of this approach is that it fully captures adaptation as each farmer adapts to the climate they have lived in. The technique measures the full net cost of climate change, including the costs as well as the benefits of adaptation. However, the technique is not concern-free. The four chapters in this paper examine important potential concerns of the cross-sectional method and how they could be addressed, especially in developing countries. Data availability is a major concern in developing countries. The first chapter looks at whether estimating impacts using individual farm data can substitute using agricultural census data at the district level that is more difficult to obtain in developing countries. The study, conducted in Sri Lanka, finds that the individual farm data from surveys are ideal for cross-sectional analysis. Another anticipated problem with applying the cross-sectionalapproach to developing countries is the absence of weather stations, or discontinued weather data sets. Further, weather stations tend to be concentrated in urban settings. Measures of climate across the landscape, especially where farms are located, are difficult to acquire. The second chapter compares the use of satellite data with ground weather stations. Analyzing these two sources of information, the study reveals that satellite data can explain more of the observed variation in farm performance than ground station data. Because satellite data are readily available for the entire planet, the availability of climate data will not be a constraint. A continuing debate is whether farm performance depends on just climate normals-the average weather over a long period of time-or on climate variance (variations away from the climate normal). Chapter 3 reveals that climate normals and climate variance are highly correlated. By adding climate variance, the studies can begin to measure the importance of weather extremes as well as normals. A host of studies have revealed that climate affects agricultural performance. Since agriculture is a primary source of income in rural areas, it follows that climate might explain variations in rural income. This is tested in the analysis in Chapter 4 and shown to be the case. The analysis reveals that local people in rural areas could be heavily affected by climate change even in circumstances when the aggregate agricultural sector in the country does fine.

Suggested Citation

  • Mendelsohn, Robert & Dinar, Ariel & Basist, Alan & Kurukulasuriya, Pradeep & Ihsan Ajwad, Mohamed & Kogan, Felix & Williams, Claude, 2004. "Cross-sectional analyses of climate change impacts," Policy Research Working Paper Series 3350, The World Bank.
    • Handle: RePEc:wbk:wbrwps:3350
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    References listed on IDEAS

    as
    1. Mendelsohn, Robert & Nordhaus, William D & Shaw, Daigee, 1994. "The Impact of Global Warming on Agriculture: A Ricardian Analysis," American Economic Review, American Economic Association, vol. 84(4), pages 753-771, September.
    2. Mendelsohn, Robert & Dinar, Ariel & Sanghi, Apurva, 2001. "The effect of development on the climate sensitivity of agriculture," Environment and Development Economics, Cambridge University Press, vol. 6(1), pages 85-101, February.
    3. Robert Mendelsohn & Ariel Dinar, 2003. "Climate, Water, and Agriculture," Land Economics, University of Wisconsin Press, vol. 79(3), pages 328-341.
    4. Jinxia Wang & Robert Mendelsohn & Ariel Dinar & Jikun Huang & Scott Rozelle & Lijuan Zhang, 2009. "The impact of climate change on China's agriculture," Agricultural Economics, International Association of Agricultural Economists, vol. 40(3), pages 323-337, May.
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    Cited by:

    1. Eriyagama, Nishadi & Smakhtin, Vladimir U. & Chandrapala, Lalith & Fernando, Karin, 2010. "Impacts of climate change on water resources and agriculture in Sri Lanka: a review and preliminary vulnerability mapping," IWMI Research Reports 94787, International Water Management Institute.
    2. Quiroga, Sonia & Iglesias, Ana, 2007. "Projections of economic impacts of climate change in agriculture in Europe," Economia Agraria y Recursos Naturales, Spanish Association of Agricultural Economists, vol. 7(14), pages 1-18.
    3. Kaixing Huang & Nicholas Sim, 2018. "Why do the econometric-based studies on the effect of warming on agriculture disagree? A meta-analysis," Oxford Economic Papers, Oxford University Press, vol. 70(2), pages 392-416.

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