Abstract
The success of the Green Revolution in Punjab, India, is threatened by a significant decline in water resources. Punjab, a major agricultural supplier for the rest of India, supports irrigation with a canal system and groundwater, which is vastly overexploited. The detailed data required to estimate future impacts on water supplies or develop sustainable water management practices is not readily available for this region. Therefore, we use Bayesian methods to estimate hydrologic properties and irrigation requirements for an under-constrained mass balance model. Using the known values of precipitation, total canal water delivery, crop yield, and water table elevation, we present a method using a Markov chain Monte Carlo (MCMC) algorithm to solve for a distribution of values for each unknown parameter in a conceptual mass balance model. Model results are used to test three water management strategies, which show that replacement of rice with pulses may be sufficient to stop water table decline. This computational method can be applied in data-scarce regions across the world, where integrated water resource management is required to resolve competition between food security and available resources.
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Acknowledgments
We thank colleagues at the Punjab Agricultural University (Ludhiana, India), the Central Groundwater Board, and the Bhakra Beas Management Board (both from Chandigarh, India) for sharing valuable data. This work was completed with funding from the Columbia University Earth Institute Postdoctoral Fellowship program and the International Development Research Centre (Canada).
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Russo, T.A., Devineni, N., Lall, U. (2015). Assessment of Agricultural Water Management in Punjab, India, Using Bayesian Methods. In: Setegn, S., Donoso, M. (eds) Sustainability of Integrated Water Resources Management. Springer, Cham. https://doi.org/10.1007/978-3-319-12194-9_9
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