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IRRIGATION WATER PRODUCTIVITY AS AFFECTED BY WATER MANAGEMENT IN A SMALL-SCALE IRRIGATION SCHEME IN THE BLUE NILE BASIN, ETHIOPIA

Published online by Cambridge University Press:  14 January 2011

SISAY DEMEKU DERIB ,
KATRIEN DESCHEEMAEKER ,
AMARE HAILESLASSIE  and
TILAHUN AMEDE
SISAY DEMEKU DERIB*
Affiliation:
Sirinka Agricultural Research Center (SARC), P.O Box 74, Woldya, Ethiopia
KATRIEN DESCHEEMAEKER
Affiliation:
International Livestock Research Institute (ILRI), P.O Box 5689, Addis Ababa, Ethiopia International Water Management Institute (IWMI), P.O Box 5689, Addis Ababa, Ethiopia
AMARE HAILESLASSIE
Affiliation:
International Livestock Research Institute (ILRI), P.O Box 5689, Addis Ababa, Ethiopia
TILAHUN AMEDE
Affiliation:
International Livestock Research Institute (ILRI), P.O Box 5689, Addis Ababa, Ethiopia International Water Management Institute (IWMI), P.O Box 5689, Addis Ababa, Ethiopia
*
††Corresponding author. [email protected]
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Summary

In Ethiopia, irrigation is mainly implemented in small-scale irrigation schemes, which are often characterized by low water productivity. This study reports on the efficiency and productivity of a typical small-scale irrigation scheme in the highlands of the Blue Nile, Ethiopia. Canal water flows and the volume of irrigation water applied were measured at field level. Grain and crop residue biomass and grass biomass production along the canals were also measured. To triangulate the measurements, the irrigation farm management, effects of water logging around irrigation canals, farm water distribution mechanisms, effects of night irrigation and water losses due to soil cracking created by prolonged irrigation were closely observed. The average canal water loss from the main, the secondary and the field canals was 2.58, 1.59 and 0.39 l s−1 100 m−1, representing 4.5, 4.0 and 26% of the total water flow respectively. About 0.05% of the loss was attributed to grass production for livestock, while the rest was lost through evaporation and canal seepage. Grass production for livestock feed had a land productivity of 6190.5 kg ha−1 and a water productivity of 0.82 kg m−3. Land productivity for straw and grain was 2048 and 770 kg ha−1, respectively, for teff, and 1864 kg ha−1 and 758 kg ha−1, respectively, for wheat. Water productivities of the crops varied from 0.2 to 1.63 kg m−3. A significant volume of water was lost from small-scale irrigation systems mainly because farmers' water application did not match crop needs. The high price incurred by pumped irrigation positively affected water management by minimizing water losses and forced farmers to use deficit irrigation. Improving water productivity of small-scale irrigation requires integrated interventions including night storage mechanisms, optimal irrigation scheduling, empowerment of farmers to maintain canals and proper irrigation schedules.

Type
Research Article
Information
Experimental Agriculture , Volume 47 , Issue S1: Improving Water Productivity of Crop-Livestock Systems in Drought-prone Regions , January 2011 , pp. 39 - 55
Copyright
Copyright © Cambridge University Press 2011

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References

REFERENCES

Akkuzu, E., Unal, H. B. and Karatafi, B. S. (2007). Determination of water conveyance loss in the menemen open canal irrigation network. Turkish Journal of Agriculture and Forestry 31: 1122.Google Scholar
Allen, R. G., Pereira, L. S., Reas, D. and Smith, M. (1998). Crop evapotranspiration: guidelines for computing crop water requirements, FAO Irrigation and Drainage Paper 56. FAO- Food and Agriculture Organization of the United Nations, Rome.Google Scholar
Awulachew, S. B., Yilma, A. D., Loulseged, M., Loiskandl, W., Ayana, M. and Alamirew, T. (2007). Water resources and irrigation development in Ethiopia. IWMI Working Paper 123.Google Scholar
Awulachew, S. B., Merrey, D. J., Kamara, A. B., Van Koopen, B., De Vries, F. Penning and Boelle, E. (2005). Experiences and opportunities for promoting small-scale/micro irrigation and rainwater harvesting for food security in Ethiopia. IWMI Working Paper 98.Google Scholar
Bakry, M. F. and Awad, A. M. (1997). Practical estimation of seepage losses along earthen canals in Egypt. Water Resources Management 11: 197206.CrossRefGoogle Scholar
Bekele, S. and Tilahun, K. (2007). Regulated deficit irrigation scheduling of onion in a semiarid region of Ethiopia. Agricultural Water Management 89: 148152.CrossRefGoogle Scholar
Clemmens, A. J., Bos, M. G. and Replogle, J. A. (1984). Portable RBC flumes for furrows and earthen channels. Transaction of ASAE 27: 10161021.CrossRefGoogle Scholar
Deneke, T. T. (2010). Institutional implications of governance of local common pool resources on livestock water productivity in Ethiopia. Experimental Agriculture 46: Suppl. 00–00.Google Scholar
Eijkelkamp, . Operating Instructions 13.17.02 RBC Flume. Hog Flume Software. http://www.eijkelkamp.com/Portals/2/Eijkelkamp/Files/Manuals/M2-131702e%20RBC-Flume.pdf [Accessed on 5 October 2010].Google Scholar
FAO. (2009). CROPWAT 8.0 for Windows. Rome, Italy. http://www.fao.org/nr/water/infores_databases_cropwat.html [Accessed 5 October 2010]Google Scholar
FAO. (1993). Agro-ecological land resources assessment for agricultural development planning-a case study of Kenya resources data base and land productivity. Technical Annex 5, Rome, Italy.Google Scholar
FAO. (1978). Effective rainfall in irrigated agriculture. FAO Irrigation and Drainage Paper 25.Google Scholar
Faulkner, J. W., Steenhuis, T., de Giesen, N. V., Andreini, M. and Liebe, J. R. (2008). Water use and productivity of two small reservoir irrigation schemes in Ghana's upper east region. Irrigation and Drainage. 57: 151163.CrossRefGoogle Scholar
Haileslassie, A., Peden, D., Gebreselassie, S, Amede, T., Wagnew, A. and Taddesse, A. (2009a). Livestock water productivity in the Blue Nile Basin: assessment of farm scale heterogeneity. The Range land Journal 31: 213222.CrossRefGoogle Scholar
Haileslassie, A, Peden, D., Gebreselassie, S., Amede, T., and Descheemaeker, K. (2009b). Livestock water productivity in mixed crop–livestock farming systems of the Blue Nile basin: Assessing variability and prospects for improvement. Agricultural System. 102: 3340.CrossRefGoogle Scholar
Kloezen, W. H., and Garcés-Restrepo, C. (1998). Assessing irrigation performance with comparative indicators: The case of the Alto Rio Lerma Irrigation District, Mexico. Research Report 22. Colombo, Sri Lanka: International Water Management Institute.Google Scholar
Levine, G. (1982). Relative water supply: An explanatory variable for irrigation systems. Technical Report 6. Ithaca, New York: Cornell University.Google Scholar
MCE, (Metaferia Consulting Engineers) (2001). Assessment of experiences and opportunities on medium and large scale irrigation in Ethiopia. Metaferia Consulting Engineers. Addis Ababa: Ethiopia.Google Scholar
MoFED, (Ministry of Finance and Economic Development). (2006). Ethiopia: Building on progress, a plan for accelerated and sustained development to end poverty (PASDEP) 2005/06-2009/10, September, 2006, Ministry of Finance and Economic Development, Addis Ababa: Ethiopia.Google Scholar
Molden, D. J., and Gates, T. K. (1990). Performance measures for evaluation of irrigation water delivery systems. Journal of Irrigation and Drainage Engineering 116: 804823.CrossRefGoogle Scholar
Molden, D. J., Sakthivadivel, R., Perry, C. J., de Fraiture, C. and Kloezen, W. H. (1998). Indicators for comparing performance of irrigated agricultural systems. Research Report 20. Colombo, Sri Lanka: International Water Management Institute.Google Scholar
MoWR, (Ministry of Water Resources). (1999). Water Resource Management Policy, Addis Ababa: Ethiopia. Ministry of Water Resources.Google Scholar
MoWR, (Ministry of Water Resources). (2008). Gumara Irrigation Project Feasibility Study Report. Ministry of Water Resources, Addis Ababa. Ethiopia.Google Scholar
NAS, (National Academy of Science). (1996). Lost Crops of Africa: Volume I: Grains. Washington, USA: National Academy Press.Google Scholar
Perry, C. J. (1996). The IIMI water balance framework: A model for project level analysis. Research Report 5. Colombo, Sri Lanka: International Irrigation Management Institute.Google Scholar
Robel, Lambiso. (2005). Assessment of design practices and performance of small-scale irrigation structures in South Region, MSc Thesis, Arbaminch University, Ethiopia.Google Scholar
Skogerboe, G. V., Bennett, R. S. and Walker, W. R. (1973). Selection and installation of cutthroat flumes for measuring irrigation and drainage water. Colorado State University Experimental Station, Fort Collins Technical Bulletin 120.Google Scholar
SPSS Inc. (2004). SPSS 13.0 Computer Statistics Software: instruction manual. Chicago, USA.Google Scholar
Turner, B. (1994). Small-scale irrigation in developing countries. Land Use Policy 11: 251261.CrossRefGoogle Scholar
Unal, H. B., Asik, S., Avci, M., Yasar, S. and Akkuzu, E. (2004). Performance of water delivery system at tertiary canal level: a case study of the Menemen Left Bank Irrigation System, Gediz Basin, Turkey. Agricultural Water Management 65: 155171.CrossRefGoogle Scholar
Vincent, L. (1994). Lost chances and new futures: interventions and institutions in small-scale irrigation. Land Use Policy 11: 309322.CrossRefGoogle Scholar
Vincent, L. (2003). Towards a smallholder hydrology for equitable and sustainable water management. Natural Resources Forum 27: 108116.CrossRefGoogle Scholar