Abstract
Crop water productivity (WP) in irrigated agriculture is a key for food and environmental security, in particular when water becomes scarce, as has been predicted for downstream regions in the Aral Sea basin. The assessment of WP for each field crop is hampered when farmers cultivate several crops at the same time and on the same fields and cannot record water allocation for each crop. Since results from the commonly used Ordinary Least Squares (OLS) approach turned out to be unreliable and in some cases even had negative values, we combined a behavioral approach with mixed estimation methods to estimate water allocation for each crop over larger areas and over various years with limited data availability. Unobserved crop specific input data was derived from aggregated data using the mixed estimation method for the case study region Khorezm, located in northwestern Uzbekistan. On the basis of actual water usage, spatial (for different administrative districts in Khorezm) and temporal (for the years 2004–2007) distributions of WP for cotton, wheat, rice, vegetables (including melons), and fruits were estimated and visualized through contour diagrams. All crops, except forage, used much more irrigation water than the recommended amount, with cotton and rice being the highest water consumers. For example, cotton was almost 64% over-irrigated compared to the recommended amounts. Even though rice was cropped on a relatively small share of the total land in Khorezm (less than 10% of the total arable land), about 30% of the total crop irrigation water was applied on rice. WP depends on district or farms’ location declining proportionally to the distance from the water source, due to high conveyance losses and low yields monitored at the tail ends of the irrigation system. Extremely high water losses on both conveyance and field level revealed much scope for water saving by implementing different water-wise options such as lining canals, introducing best water use practices and producing less water consuming crops. This would, in turn, allow increasing crop yields and WP particularly in downstream districts. Furthermore, the comparison of WP among different crops and different districts allowed determining the potential suitability of certain districts for certain crops, which suggests that a more regionally differentiated cropping portfolio, according to water availability, soil quality and similar parameters, would improve overall system WP, and hence sustainability of the agricultural production.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Abdullaev I, De Fraiture C, Giordano M, Yakubov M, Rasulov A (2009) Agricultural water use and trade in Uzbekistan: situation and potential impacts of market liberalization. Int J Water Resour Dev 25(1):47–63
Awan UK (2010) Coupling hydrological and irrigation schedule models for the management of surface and groundwater resources in Khorezm, Uzbekistan. Ecology and development series no. 73, ZEF/University of Bonn, Bonn
Awan UK, Tischbein B, Martius C, Hafeez M, Kamalov P (2011) Modeling irrigation scheduling under shallow groundwater conditions as a tool for an integrated management of surface and groundwater resources. In: Martius C, Rudenko I, Lamers JPA, Vlek PLG (eds) Cotton, water, salts and Soums: economic and ecological restructuring in Khorezm, Uzbekistan. Springer, Dordrecht/Berlin/Heidelberg/New York
Bekchanov M, Karimov A, Lamers JPA (2010a) Impact of water availability on land and water productivity: a temporal and spatial analysis of the case study region Khorezm, Uzbekistan. Water 2:668–684
Bekchanov M, Lamers JPA, Martius C (2010b) Pros and cons of adopting water-wise approaches in the lower reaches of the Amu Darya: a socio-economic view. Water 2:200–216
Bobojonov I, Lamers JPA (2008) Analysis of agricultural markets in Khorezm, Uzbekistan. In: Wehrheim P, Schoeller-Schletter A, Martius C (eds) Continuity and change: land and water use reforms in rural Uzbekistan. Socio-economic and legal analyses for the region Khorezm. IAMO, Halle/Saale, pp 165–182
Bobojonov I, Lamers JPA, Djanibekov N, Ibragimov N, Begdullaeva T, Ergashev A, Kienzler K, Eshchanov R, Rakhimov A, Ruzimov J, Martius C (2011) Crop diversification in support of sustainable agriculture in Khorezm. In: Martius C, Rudenko I, Lamers JPA, Vlek PLG (eds) Cotton, water, salts and Soums: economic and ecological restructuring in Khorezm, Uzbekistan. Springer, Dordrecht/Berlin/Heidelberg/New York
Conrad C (2006) Remote sensing based modeling and hydrological measurements to assess the agricultural water use in the Khorezm region, Uzbekistan. PhD dissertation, University of Wuerzburg, Wuerzburg
Conrad C, Dech SW, Hafeez M, Lamers JPA, Tischbein B (2011) Remote sensing and hydrological measurement based irrigation performance assessments in the upper Amu Darya Delta, Central Asia. Phys Chem Earth (in press)
Devkota KP (2011) Resource Utilization and Sustainability of Conservation Based Rice-Wheat Cropping Systems. PhD dissertation, Bonn University, Bonn
Djanibekov N, Bobojonov I, Lamers JPA (2011) Farm reform in Uzbekistan. In: Martius C, Rudenko I, Lamers JPA, Vlek PLG (eds) Cotton, water, salts and Soums: economic and ecological restructuring in Khorezm, Uzbekistan. Springer, Dordrecht/Berlin/Heidelberg/New York
Dukhovny VA, Sokolov VI (2002) Lessons on cooperation building to manage water conflicts in the Aral Sea Basin. Technical documents in hydrology: PC-CP Series: 11
Forkutsa I, Sommer R, Shirokova YI, Lamers JPA, Kienzler K, Tischbein B, Martius C, Vlek PLG (2009) Modeling irrigated cotton with shallow groundwater in the Aral Sea Basin of Uzbekistan: I. Water dynamics. Irrig Sci 27(4):331–346
Golan A, Judge G, Miller D (1996) Maximum entropy econometrics: robust estimation with limited data. Wiley, New York
Greene WH (2003) Econometric analysis, 5th edn. Prentice-Hall, New Jersey
Hydromet (2007) The state water cadastre: surface and ground water resources use and quality, Center of Hydrometeorological Service at the Cabinet of the Ministers of Uzbekistan Tashkent
HydroModRay (2002) Average requirements for water use for different crops in Khorezm, Urgench. Khorezm Department of Land and Water Resources of the Ministry of Agriculture and Water Resources
Just RE, Zilberman D, Hochman E, Bar-Shira Z (1990) Input allocation in multicrop systems. Am J Agric Econ 72(1):200–209
Lence SH, Miller DJ (1998) Estimation of multi-output production functions with incomplete data: a generalized maximum entropy approach. Eur Rev Agric Econ 25(2):188–209
Manschadi AM, Oberkircher L, Tischbein B, Conrad C, Hornidge A-K, Bhaduri A, Schorcht G, Lamers J, Vlek PLG (2010) White Gold’ and Aral Sea disaster – towards more efficient use of water resources in the Khorezm region, Uzbekistan. Lohmann Info 45(1):34–47
Martius C, Lamers JPA, Wehrheim P, Schoeller-Schletter A, Eshchanov R, Tupitsa A, Khamzina A, Akramkhanov A, Vlek PLG (2004) Developing sustainable land and water management for the Aral Sea Basin through an interdisciplinary research. In: Seng V, Craswell E, Fukai S (eds) Water in agriculture. ACIAR proceedings no. 116, Canberra
Micklin P (1988) Dessiccation of the Aral Sea: a water management disaster in the soviet union. Science 241(4870):1170–1176
Micklin P (2002) Water in the Aral Sea Basin of Central Asia: cause of conflict or cooperation? Eur Geogr Econ 43(7):505–528
Müller M (2006) A general equilibrium approach to modeling water and land use reforms in Uzbekistan. PhD dissertation, Bonn University, Bonn
Müller M (2008) Where has all the water gone? In: Wehrheim P, Shoeller-Schletter A, Martius C (eds) Continuity and change: land and water use reforms in rural Uzbekistan. IAMO series 43:89–104
OblSelVodKhoz (2008) Data on norms, limits and usage of irrigation water from 2004 to 2007, Urgench. Khorezm Department of Land and Water Resources of the Ministry of Agriculture and Water Resources
OblStat (2008) Agricultural indicators for Khorezm oblast, 2000–2007. Khorezm Region Department of Statistics
Oweis T, Hachum A (2006) Water harvesting and supplemental irrigation for improved water productivity of dry land farming in West Asia and North Africa. Agric Water Manag 80:57–73
Shi Z, Ruecker GR, Mueller M, Conrad C, Ibragimov N, Lamers JPA, Martius C, Struntz G, Dech S, Vlek PLG (2007) Modeling of cotton yields in the Amu Darya river floodplains of Uzbekistan integrating multitemporal remote sensing and minimum field data. Agron J 99:1317–1326
Theil H, Goldberger AS (1961) On pure and mixed statistical estimation in economics. Int Econ Rev 2(1):65–78
Tischbein B, Awan UK, Abdullaev I, Bobojonov I, Conrad C, Forkutsa I, Ibrakhimov M, Poluasheva G (2011) Water management in Khorezm: current situation and options for improvement (hydrological perspective). In: Martius C, Rudenko I, Lamers JPA, Vlek PLG (eds) Cotton, water, salts and Soums: economic and ecological restructuring in Khorezm, Uzbekistan. Springer, Dordrecht/Berlin/Heidelberg/New York
Veldwisch GJ (2008) Cotton, rice & water: transformation of agrarian relations, irrigation technology and water distribution in Khorezm, Uzbekistan. PhD dissertation, Bonn University, Bonn
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2012 Springer Science+Business Media B.V.
About this chapter
Cite this chapter
Bekchanov, M., Lamers, J.P.A., Karimov, A., Müller, M. (2012). Estimation of Spatial and Temporal Variability of Crop Water Productivity with Incomplete Data. In: Martius, C., Rudenko, I., Lamers, J., Vlek, P. (eds) Cotton, Water, Salts and Soums. Springer, Dordrecht. https://doi.org/10.1007/978-94-007-1963-7_20
Download citation
DOI: https://doi.org/10.1007/978-94-007-1963-7_20
Published:
Publisher Name: Springer, Dordrecht
Print ISBN: 978-94-007-1962-0
Online ISBN: 978-94-007-1963-7
eBook Packages: Biomedical and Life SciencesBiomedical and Life Sciences (R0)