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Water Productivity in Agriculture: Looking for Water in the Agricultural Productivity and Efficiency Literature

Susanne Scheierling

World Bank, Washington DC, USA

E-mail Address: sscheierling@worldbank.org

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David O. Treguer

World Bank, Washington DC, USA

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, and

James F. Booker

Siena College, Loudonville, NY, USA

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https://doi.org/10.1142/S2382624X16500077Cited by:23 (Source: Crossref)

Abstract

Expectations are that the agricultural sector will have to expand the use of water for irrigation to meet rising food demand, while at the same time the competition for water resources is growing in many regions. Increasing water productivity in agriculture is widely seen as a critical response to help address this challenge. Yet much of the public debate is vague on the meaning of agricultural water productivity — often emphasizing “more crop per drop” as if water were the only input that mattered —, and approaches for assessing and increasing water productivity are seldom addressed systematically. This paper discusses conceptual issues that should be kept in mind when assessing agricultural water productivity, and presents findings from what may be the first survey of the agricultural productivity and efficiency literature with regard to the explicit inclusion of water aspects in productivity and efficiency measurements. The survey comprises studies applying single-factor productivity (SFP) measures, total factor productivity (TFP) indices and frontier models. Studies using deductive methods are also included. A key finding is that the studies tend to either incorporate field- and basin-level aspects but focus only on a single input (water), or they apply multi-factor approaches but do not tackle the basin-level aspects. It seems that no study has yet presented an approach that accounts for multiple inputs and basin-level issues. Deductive methods may provide the flexibility to overcome some of the limitations of the other methods.

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References

Alauddin, M and BR Sharma [2013] Inter-district rice water productivity differences in Bangladesh: An empirical exploration and implications, Ecological Economics 93, 210–218. Crossref, Google Scholar
Alexandratos, N and J Bruinsma (2012). World agriculture towards 2030/2050: The 2012 revision. ESA Working Paper No. 12-03, Food and Agriculture Organization of the United Nations, Rome. Google Scholar
Ali, M and J Flinn [1989] Profit efficiency among basmati rice producers in Pakistan Punjab, American Journal of Agricultural Economics 71 (2), 303–310. Crossref, Google Scholar
Alston, JM and PG Pardey [2014] Agriculture in the global economy, Journal of Economic Perspectives 28 (1), 121–146. Crossref, Google Scholar
Alston, JM, BA Babcock and PG Pardey (eds.) [2010a] The Shifting Patterns of Agricultural Production and Productivity Worldwide. Ames, Iowa: The Midwest Agribusiness Trade Research and Information Center. Google Scholar
Alston, JM, BA Babcock and PG Pardey [2010b] Shifting patterns of agricultural production and productivity: Synthesis and conclusion, The Shifting Patterns of Agricultural Production and Productivity Worldwide, Alston, JM, B A Babcock and P G Pardey (eds.), Ames, Iowa: The Midwest Agribusiness Trade Research and Information Center, pp. 63–95. Google Scholar
Annan, K (2000). Address of Secretary General Kofi Annan to the “Group of 77” Developing Countries. South Summit, Havana, Cuba. Press Release SG/SM/7358. New York: United Nations. Google Scholar
Antle, JM and SM Capalbo [1988] Introduction and overview, Agricultural Productivity: Measurement and Explanation, Capalbo, SM and JM Antle (eds.), Washington, DC: Resources for the Future, pp. 1–14. Google Scholar
Arbat, GP, FR Lamm and AA Kheira [2010] Subsurface drip irrigation emitter spacing effects on soil water redistribution, corn yield, and water productivity, Applied Engineering in Agriculture 26 (3), 391–399. Crossref, Google Scholar
Barker, R, D Dawe and A Inocencio [2003] Economics of water productivity in managing water for agriculture, Water Productivity in Agriculture: Limits and Opportunities for Improvement, Kijne, JW, R Barker and D Molden (eds.), Wallingford, UK: CAB International, pp. 19–36. Crossref, Google Scholar
Belloumi, M and MS Matoussi [2006] Date yield and water productivity in Nefzaoua Oases of Tunisia: A comparative analysis, New Medit: Mediterranean Journal of Economics, Agriculture and Environment 5 (2), 52–60. Google Scholar
Bessembinder, J, P Leffelaar, A Dhindwal and T Ponsioen [2005] Which crop and which drop, and the scope for improvement of water productivity, Agricultural Water Management 73 (2), 113–130. Crossref, Google Scholar
Booker, JF, RE Howitt, AM Michelsen and RA Young [2012] Economics and the modeling of water resources and policies, Natural Resource Modeling 25 (1), 168–218. Crossref, Google Scholar
Bravo-Ureta, B, D Solis, VM Lopez, J Maripani, A Thiam and T Rivas [2007] Technical efficiency in farming: A meta-regression analysis, Journal of Productivity Analysis 27, 57–72. Crossref, Google Scholar
Bredehoeft, JD and RA Young [1970] Conjunctive use of groundwater and surface water for irrigated agriculture: Risk aversion, Water Resources Research 19 (5), 1111–1121. Crossref, Google Scholar
Caswell, MF and D Zilberman [1986] The effects of well depth and land quality on the choice of irrigation technology, American Journal of Agricultural Economics 68 (4), 798–811. Crossref, Google Scholar
Coelli, T, DSP Rao, C O’Donnell and G Battese [2005] An Introduction to Efficiency and Productivity Analysis, 2nd edn. New York: Springer. Google Scholar
Conradie, B, J Piesse and C Thirtle [2009] District-level total factor productivity in agriculture: Western Cape Province, South Africa, 1952–2002, Agricultural Economics 40, 265–280. Crossref, Google Scholar
Diao, X, A Dinar, T Roe and Y Tsur [2008] A general equilibrium analysis of conjunctive ground and surface water use with an application to Morocco, Agricultural Economics 38 (2), 117–135. Crossref, Google Scholar
Ekanayake, S and S Jayasuriya [1987] Measurement of firm-specific technical efficiency: A comparison of methods, Journal of Agricultural Economics 38 (1), 115–122. Crossref, Google Scholar
Farrell, MJ [1957] The measurement of productive efficiency, Journal of the Royal Statistical Society Series A (General) 120 (3), 253–290. Crossref, Google Scholar
FAO (Food and Agriculture Organization of the United Nations) (2012). Coping with Water Scarcity: An Action Framework for Agriculture and Food Security. FAO Water Reports 38, FAO, Rome. Google Scholar
Fraser, I and D Cordina [1999] An application of data envelopment analysis to irrigated dairy farms in Northern Victoria, Australia, Agricultural Systems 59, 267–282. Crossref, Google Scholar
Fried, H, CAK Lovell and SS Schmidt [2007] Efficiency and productivity, The Measurement of Productive Efficiency and Productivity, Fried, HO, CAK Lovell and SS Schmidt (eds.), New York, NY: Oxford University Press, pp. 1–106. Google Scholar
Frisvold, G, L Jackson, J Pritchett and J Ritten [2013] Agriculture and ranching, Assessment of Climate Change in the Southwest United States: A Report Prepared for the National Climate Assessment, Garfin, G, A Jardine, R Merideth, M Black and S LeRoy (eds.), A report by the Southwest Climate Alliance, Washington, DC: Island Press, pp. 218–239. Crossref, Google Scholar
Fuglie, KO [2010a] Indonesia: from food security to market-led agricultural growth, The Shifting Patterns of Agricultural Production and Productivity Worldwide, Alston, JM, BA Babcock and PG Pardey (eds.), Ames, Iowa: The Midwest Agribusiness Trade Research and Information Center, pp. 343–377. Google Scholar
Fuglie, KO [2010b] Total factor productivity in the global agricultural economy: Evidence from FAO data, The Shifting Patterns of Agricultural Production and Productivity Worldwide, Alston, JM, BA Babcock and PG Pardey (eds.), Ames, Iowa: The Midwest Agribusiness Trade Research and Information Center, pp. 63–95. Google Scholar
Fuglie, KO, SL Wang and VE Ball [2012a] (eds.) Productivity Growth in Agriculture: An International Perspective. Wallingford: CAB International. Crossref, Google Scholar
Fuglie, KO, SL Wang and VE Ball [2012b] Introduction to productivity growth in agriculture, Productivity Growth in Agriculture: An International Perspective, Fuglie, KO, SL Wang and VE Ball (eds.), Wallingford: CAB International, pp. 1–12. Crossref, Google Scholar
Gebregziabher, G, RE Namara and S Holden [2012] Technical efficiency of irrigated and rain-fed smallholder agriculture in Tigray, Ethiopia: A comparative stochastic frontier production function analysis, Quarterly Journal of International Agriculture 51 (3), 203–226. Google Scholar
Gedara, KM, C Wilson, S Pascoe and T Robinson [2012] Factors affecting technical efficiency of rice farmers in village reservoir irrigation systems of Sri Lanka, Journal of Agricultural Economics 63 (3), 627–638. Crossref, Google Scholar
Gollop, FM and GP Swinand [1998] From total factor to total resource productivity: An application to agriculture, American Journal of Agricultural Economics 80, 577–583. Crossref, Google Scholar
Harlmann, LM and D Seastone [1965] Efficiency criteria for market transfer of water, Water Resources Research 1 (2), 165–171. Crossref, Google Scholar
Harou, J, M Pulido-Velazquez, DE Rosenberg, J Medellín-Azuara, JR Lund and RE Howitt [2009] Hydro-economic models: Concepts, design, applications, and future prospects, Journal of Hydrology 375 (3), 627–643. Crossref, Google Scholar
Hartman, LM and N Whittlesey (1961). Marginal values of irrigation water: A linear programming analysis of farm adjustments to changes in water supply. Technical Bulletin 70, Agricultural Experiment Station, Colorado State University, Fort Collins, CO. Google Scholar
Heady, EO and JL Dillon [1961] Agricultural Production Functions. Ames, Iowa: Iowa State University Press. Google Scholar
Heady, EO, HC Madsen, KJ Nicol and SH Hargrave [1973] National and interregional models of water demand, land use, and agricultural policies, Water Resources Research 9 (4), 777–797. Crossref, Google Scholar
Howitt, R, W Watson and R Adams [1980] A reevaluation of price elasticities for irrigation water, Water Resources Research 16 (4), 623–628. Crossref, Google Scholar
Howitt, RE [1995] Positive mathematical programming, American Journal of Agricultural Economics 77 (2), 329–342. Crossref, Google Scholar
Hsiao, TC, P Steduto and E Fereres [2007] A systematic and quantitative approach to improve water use efficiency in agriculture, Irrigation Science 25 (3), 209–231. Crossref, Google Scholar
Huffaker, R [2008] Conservation potential of agricultural water conservation subsidies, Water Resources Research 44, W00E01, doi: 10.1029/2007WR006183. Crossref, Google Scholar
Huffaker, R and N Whittlesey [1995] Agricultural water conservation legislation: Will it save water?, Choices 10 (4), 24–28. Google Scholar
Huffaker, R and N Whittlesey [2000] The allocative efficiency and conservation potential of water laws encouraging investments in on-farm irrigation technology, Agricultural Economics 24 (1), 47–60. Crossref, Google Scholar
Huffaker, R and N Whittlesey [2003] A theoretical analysis of economic incentive policies encouraging agricultural water conservation, Water Resources Development 19 (1), 37–55. Crossref, Google Scholar
Israelsen, OW [1950] Irrigation Principles and Practices. New York: Wiley. Crossref, Google Scholar
Jensen, ME [2007] Beyond irrigation efficiency, Irrigation Science 25 (3), 233–245. Crossref, Google Scholar
Jin, S, J Huang and S Rozelle [2010] Agricultural productivity in China, The Shifting Patterns of Agricultural Production and Productivity Worldwide, Alston, JM, BA Babcock and PG Pardey (eds.), Ames, Iowa: The Midwest Agribusiness Trade Research and Information Center, pp. 229–278. Google Scholar
Jury, W.A and H Vaux Jr. [2005] The role of science in solving the world’s emerging water problems, Proceedings of the National Academy of Sciences 102 (44), 15715–15720. Crossref, Google Scholar
Karagiannis, G, V Tzouvelekas and A Xepapadeas [2003] Measuring irrigation water efficiency with a stochastic production frontier, Environment and Resource Economics 26, 57–72. Crossref, Google Scholar
Latruffe, L (2010). Competitiveness, productivity and efficiency in the agricultural and agri-food sectors. OECD Food, Agriculture and Fisheries Papers, No. 30, OECD Publishing, Paris. Google Scholar
Liu, J, J Williams, A Zehnder and H Yang [2007] GEPIC - modelling wheat yield and crop water productivity with high resolution on a global scale, Agricultural Systems 94, 478–493. Crossref, Google Scholar
McGuckin, T, N Gollehon and S Ghosh [1992] Water conservation in irrigated agriculture: A stochastic production frontier model, Water Resources Research 28 (2), 305–312. Crossref, Google Scholar
Medellín-Azuara, J, RE Howitt, C Waller-Barrera, LG Mendoza-Espinosa, JR Lund and JE Taylor [2009] A calibrated agricultural water demand model for three regions in Northern Baja California, Agrosciencia 43 (2), 83–96. Google Scholar
Molden, D (1997). Accounting for water use and productivity. System-Wide Initiative for Water Management (SWIM) Paper 1, International Water Management Institute, Colombo, Sri Lanka. Google Scholar
Molden, D and R Sakthivadivel [1999] Water accounting to assess use and productivity of water, International Journal of Water Resources Development 1 (1–2), 55–71. Crossref, Google Scholar
Molden, D and TY Oweis [2007] Pathways for increasing agricultural water productivity, Water for Food, Water for Life:A Comprehensive Assessment of Water Management in Agriculture, Molden, D (ed.), London: Earthscan and International Water Management Institute, pp. 279–310. Google Scholar
Molden, D, H Murray-Rust, R Sakthivadivel and I Makin [2003] A water-productivity framework for understanding and action, Water Productivity in Agriculture: Limits and Opportunities for Improvement, Kijne, JW, R Barker and D Molden (eds.), Wallingford, UK: CAB International, pp. 1–18. Crossref, Google Scholar
Moore, CV and TR Hedges [1963] A method for estimating the demand for irrigation water, Agricultural Economics Research 15 (4), 131–135. Google Scholar
Murgai, R (1999). The Green Revolution and the Productivity Paradox: Evidence from the Indian Punjab. Policy Research Working Papers 2234, World Bank, Washington, DC. Google Scholar
Farm subsidies leading to more water use (7 June 2003), The New York Times. Google Scholar
Peterson, JM and Y Ding [2005] Economic adjustments to groundwater depletion in the high plains: Do water-saving irrigation systems save water?, American Journal of Agricultural Economics 87 (1), 147–159. Crossref, Google Scholar
Roe, T, A Dinar, Y Tsur and X Diao [2005] Feedback links between economy-wide and farm-level policies: With application to irrigation water management in Morocco, Journal of Policy Modeling 27 (8), 905–928. Crossref, Google Scholar
Ruttan, VW [2002] Productivity growth in world agriculture: Sources and constraints, Journal of Economic Perspectives 16 (4), 161–184. Crossref, Google Scholar
Sakthivadivel, R, C de Fraiture, D Molden and C Perry [1999] Indicators of land and water productivity in irrigated agriculture, Water Resources Development 15 (1–2), 161–179. Crossref, Google Scholar
Sarker, D and S De [2004] Non-parametric approach to the study of farm efficiency in agriculture, Journal of Contemporary Asia 34 (2), 207–220. Crossref, Google Scholar
Scheierling, SM (1995). Measuring demand for irrigation water and foregone direct benefits of irrigation water transfers. Unpublished PhD dissertation, Department of Agricultural and Resource Economics, Colorado State University, Fort Collins. Google Scholar
Scheierling, SM, RA Young and GE Cardon [2006] Public subsidies for water-conserving irrigation investments: Hydrologic, agronomic and economic assessment, Water Resources Research 42 (3), W03428. Crossref, Google Scholar
Scheierling, SM, DO Treguer, JF Booker and E Decker (2014). How to assess agricultural water productivity? Looking for water in the agricultural productivity and efficiency literature. Policy Research Working Paper 6982, World Bank, Washington, DC. Google Scholar
Seckler, D (1996). The new era of water resources management: From “dry” to “wet’ water savings. Research Report 1, International Water Management Institute, Colombo, Sri Lanka. Google Scholar
Sherlund, S, C Barrett and A Adesina [2002] Smallholder technical efficiency controlling for environmental production conditions, Journal of Development Economics 69, 85–101. Crossref, Google Scholar
Taylor, RG, RD Schmidt, L Stodick and BA Contor [2014] Modeling conjunctive water use as a reciprocal externality, American Journal of Agricultural Economics 96 (3), 1–16. Crossref, Google Scholar
UNESCO (United Nations Educational, Scientific, and Cultural Organization) (2009). Water in a Changing World: The United Nations World Water Development Report 3. Paris: UNESCO Publishing; London: Earthscan. Google Scholar
Van Dam, JC, R Singh, JJE Beeembinder, PA Leffelaar, WGM Bastiaanssen, RK Jhorar, JG Kores and P Droogers [2006] Assessing options to increase water productivity in irrigated river basins using remote sensing and modelling tools, Water Resources Development 22 (1), 115–133. Crossref, Google Scholar
Vazifedoust, M, JC van Dam, RA Feddes and M Feizi [2008] Increasing water productivity of irrigated crops under limited water supply at field scale, Agricultural Water Management 95 (2), 89–102. Crossref, Google Scholar
Wadud, A and B White [2000] Farm household efficiency in Bangladesh: A comparison of stochastic frontier and DEA methods, Applied Economics 32 (13), 1665–1673. Crossref, Google Scholar
Wallander, S and M Hand (2011). Measuring the impact of the Environmental Quality Incentives Program (EQIP) on irrigation efficiency and water conservation. Selected Paper prepared for presentation at the Agricultural and Applied Economics Association’s 2011 AAEA & NAREA Joint Annual Meeting, Pittsburg, PA, July 24–26, 2011. Google Scholar
Wang, SL, F Tuan, F Gale, A Somwaru and J Hansen [2013] China’s regional agricultural productivity growth in 1985–2007: A multilateral comparison, Agricultural Economics 33, 241–251. Crossref, Google Scholar
Ward, FA and M Pulido-Velasquez [2008] Water conservation in irrigation can increase water use, Proceedings of the National Academy of Sciences (PNAS) 105 (47), 18215–18220. Crossref, Google Scholar
Wichelns, D [2014] Do estimates of water productivity enhance understanding of farm-level water management?, Water 6, 778–295. Crossref, Google Scholar
World Bank (2012). Turn Down the Heat: Why a 4°C Warmer World Must Be Avoided. A Report for the World Bank by the Potsdam Institute for Climate Impact Research and Climate Analytics. Washington, DC: World Bank. Google Scholar
World Bank, Agriculture Action Plan 2013–2015. Implementing Agriculture for Development (World Bank, Washington, DC, 2013). Google Scholar
World Economic Forum, Global Risk 2015, 10th edn. (World Economic Forum, Geneva, Switzerland, 2015). Google Scholar
World Water Assessment Program, The United Nations World Water Development Report 4: Managing Water under Uncertainty and Risk (UNESCO, Paris, 2012). Crossref, Google Scholar
Yao, R and G Shively [2007] Technical change and the productive efficiency: Irrigated rice in the Philippines, Asian Economic Journal 21 (2), 155–168. Crossref, Google Scholar
Yaron, D [1967] Empirical analysis of the demand for water by Israeli agriculture, Journal of Farm Economics 49, 461–473. Crossref, Google Scholar
Young, RA [2005] Determining the Economic Value of Water: Concepts and Methods. Washington, DC: Resources for the Future. Google Scholar
Zhao, S, Y Sheng and EM Gray [2012] Measuring productivity of the Australian broadacre and dairy industries: concepts, methodology, and data, Productivity Growth in Agriculture: An International Perspective, Fuglie, KO, SL Wang and VE Ball (eds.), Wallingford: CAB International, pp. 73–108. Crossref, Google Scholar
Zwart, S and W. Bastiaanssen [2004] Review of measured crop water productivity values for irrigated wheat, rice, cotton and maize, Agricultural Water Management 69, 115–133. Crossref, Google Scholar
Zwart, S, W Bastiaanssen, C de Fraiture and D Molden [2010a] A global benchmark map of water productivity for rainfed and irrigated wheat, Agricultural Water Management 97, 1617–1627. Crossref, Google Scholar
Zwart, S, W Bastiaanssen, C de Fraiture and D Molden [2010b] WATPRO: A remote sensing based model for mapping water productivity of wheat, Agricultural Water Management 97, 1628–1636. Crossref, Google Scholar