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Modeling Uncertainty in Large Natural Resource Allocation Problems

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  • Cai,Yongyang
  • Steinbuks,Jevgenijs
  • Judd,Kenneth L.
  • Jaegermeyr,Jonas
  • Hertel,Thomas W.

Abstract

The productivity of the world's natural resources is critically dependent on a variety of highly uncertain factors, which obscure individual investors and governments that seek to make long-term, sometimes irreversible investments in their exploration and utilization. These dynamic considerations are poorly represented in disaggregated resource models, as incorporating uncertainty into large-dimensional problems presents a challenging computational task. This study introduces a novel numerical method to solve large-scale dynamic stochastic natural resource allocation problems that cannot be addressed by conventional methods. The method is illustrated with an application focusing on the allocation of global land resource use under stochastic crop yields due to adverse climate impacts and limits on further technological progress. For the same model parameters, the range of land conversion is considerably smaller for the dynamic stochastic model as compared to deterministic scenario analysis. The scenario analysis can thus significantly overstate the magnitude of expected land conversion under uncertain crop yields.

Suggested Citation

  • Cai,Yongyang & Steinbuks,Jevgenijs & Judd,Kenneth L. & Jaegermeyr,Jonas & Hertel,Thomas W., 2020. "Modeling Uncertainty in Large Natural Resource Allocation Problems," Policy Research Working Paper Series 9159, The World Bank.
    • Handle: RePEc:wbk:wbrwps:9159
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    References listed on IDEAS

    as
    1. Jevgenijs Steinbuks & Thomas Hertel, 2016. "Confronting the Food–Energy–Environment Trilemma: Global Land Use in the Long Run," Environmental & Resource Economics, Springer;European Association of Environmental and Resource Economists, vol. 63(3), pages 545-570, March.
    2. Yongyang Cai & Kenneth Judd & Jevgenijs Steinbuks, 2017. "A nonlinear certainty equivalent approximation method for dynamic stochastic problems," Quantitative Economics, Econometric Society, vol. 8(1), pages 117-147, March.
    3. Patricio Grassini & Kent M. Eskridge & Kenneth G. Cassman, 2013. "Distinguishing between yield advances and yield plateaus in historical crop production trends," Nature Communications, Nature, vol. 4(1), pages 1-11, December.
    4. Thomas W. Hertel & Jevgenijs Steinbuks & Wallace E. Tyner, 2016. "What Is the Social Value of Second Generation Biofuels?," Applied Economic Perspectives and Policy, Agricultural and Applied Economics Association, vol. 38(4), pages 599-617.
    5. Alston, Julian M. & Pardey, Philip G., 2014. "Agricultural R&D, Food Prices, Poverty and Malnutrition Redux," Staff Papers 162413, University of Minnesota, Department of Applied Economics.
    6. Liu, Junguo & Williams, Jimmy R. & Zehnder, Alexander J.B. & Yang, Hong, 2007. "GEPIC - modelling wheat yield and crop water productivity with high resolution on a global scale," Agricultural Systems, Elsevier, vol. 94(2), pages 478-493, May.
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    Cited by:

    1. Yongyang Cai, 2020. "The Role of Uncertainty in Controlling Climate Change," Papers 2003.01615, arXiv.org, revised Oct 2020.

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