Abstract
Advanced skill in seasonal climate prediction coupled with sectoral decision models can provide decision makers with opportunities to benefit or reduce unnecessary losses. Such approaches are particularly beneficial to rainfed agriculture, the livelihood choice for the majority of the world’s poor population, for which yields are highly sensitive to climate conditions. However, a notable gap still exists between scientific communities producing predictions and the end users who may actually realize the benefits. In this study, an interdisciplinary approach connecting climate prediction to agricultural planning is adopted to address this gap. An ex ante evaluation of seasonal precipitation prediction is assessed using an agro-economic equilibrium model to simulate Ethiopia’s national economy, accounting for interannual climate variability and prediction-guided agricultural responses. Given the high spatial variability in Ethiopian precipitation, delineation of homogeneous climatic regions (i.e., regionalization) is also considered in addition to growing season precipitation prediction. The model provides perspectives across various economic indices (e.g., gross domestic product, calorie consumption, and poverty rate) at aggregated (national) and disaggregated (zonal) scales. Model results illustrate the key influence of climate on the Ethiopian economy, and prospects for positive net benefits under a prediction-guided agricultural planning (e.g., reallocation of crop types) strategy, as compared with static business-as-usual agricultural practices.
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Notes
Ethiopia produces the most teff in the world. Eritrea, India, the USA, Australia, and Netherland also produce teff. There is no teff import in the 2003 baseline and historically no known teff imports into Ethiopia. The import of teff is triggered when 55% or more of the teff area is reallocated to maize, which is a modeling possibility, but realistically less likely given the importance of this grain to Ethiopia.
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Acknowledgments
The authors thank Xinshen Diao from IFPRI who kindly shared the original EMM.
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This material is based upon work supported by the National Science Foundation under Grant No. 1545874 and the CGIAR Research Program on Water, Land and Ecosystems (WLE).
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Zhang, Y., You, L., Lee, D. et al. Integrating climate prediction and regionalization into an agro-economic model to guide agricultural planning. Climatic Change 158, 435–451 (2020). https://doi.org/10.1007/s10584-019-02559-7
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DOI: https://doi.org/10.1007/s10584-019-02559-7