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RESEARCH ARTICLE
Contents Vol 31(2)

Assessing the importance of livestock water use in basins

S. E. Cook A B , M. S. Andersson A and M. J. Fisher A
+ Author Affiliations
- Author Affiliations

A International Centre for Tropical Agriculture (CIAT), Cali, Colombia.

B Corresponding author. Email: s.cook@cgiar.org

The Rangeland Journal 31(2) 195-205 https://doi.org/10.1071/RJ09007
Submitted: 15 January 2009  Accepted: 5 May 2009   Published: 19 June 2009

Abstract

Recent concern over food prices has triggered a renewed interest in agricultural production systems. While attention is focused mainly on cropping, a complete analysis of food production systems should recognise the importance of livestock as major consumers of resources – in particular water – and as providers of food and other products and services. We propose that there is a need to examine not just food systems in isolation, but combined food and water systems, both of which are described as in a critical condition. From this broader perspective, it appears even more important to understand livestock systems because first, a total evaluation of agricultural water productivity – the gain from water consumed by agriculture – cannot be made without understanding the complexities of livestock-containing systems and; second, because in most tropical river basins, livestock systems are the major consumers of water.

To identify total water productivity of livestock-containing systems, we describe concepts of agricultural water productivity and review the complexities of tracking the flow of water through livestock-containing systems: from inputs as evapotranspiration (ET) of forage and crops to outputs of valued animal products or services. For the second part, we present preliminary results from water use accounts analysis for several major river basins, which reveal that for Africa at least, livestock systems appear to be the major water consumers. Yet, little is known about the fate of water as it passes through these systems.

We propose that livestock-containing systems offer substantial scope for increasing total water productivity and that there is considerable merit in improving the capacity to analyse water consumption and water productivity through such systems. Without removing this major source of uncertainty, the potential for systemic improvement to meet the world food and water crisis remains undefined and hence under-acknowledged.

Additional keywords: food security, livestock systems, poverty, rangeland, water productivity.


Acknowledgements

The authors are grateful to the BFP Karkheh team of the CPWF and to Michael Peters (International Centre for Tropical Agriculture, CIAT) for comments on earlier versions of this manuscript.


References


Ahmad M. D., Biggs T., Turral H., Scott C. A. (2006) Application of SEBAL approach and MODIS time-series to map vegetation water use patterns in the data scarce Krishna river basin of India. Water Science and Technology 53, 83–90.
Crossref | GoogleScholarGoogle Scholar | CAS | (verified 16 May 2009).

Cook S. E. , Gichuki F. , and Turral H. (2006). Water Productivity Assessment: Estimation at Plot, Farm and Basin scale. Basin Focal Project Working Paper No. 2. Available at: www.waterandfood.org/fileadmin/CPWF_Documents/Documents/Basin_Focal_Projects/BFP_Publications/Water_Productivity_Paper_2_final.pdf (verified 16 May 2009).

Cork S. , Peterson G. , Petschel-Held G. , Alcamo J. , Alder J. , Bennett E. , Carr E. R. , Deane D. , Nelson G. C. , Ribeiro T. , Butler C. , Mendiondo E. M. , Oluoch-Kosura W. , and Zurek M. (2005). Four scenarios. In: ‘Ecosystems and Human Well-Being: Synthesis. Vol. 2’. (Eds J. Sarukhán, A. Whyte and MA Board of Review Editors.) pp. 223–294. (Island Press: Washington, DC.) Available at: www.millenniumassessment.org/documents/document.332.aspx.pdf (verified 16 May 2009).

CPWF (Challenge Program on Water and Food) (2008). ‘Karkheh Basin Focal Project Progress Report.’ (Challenge Program on Water and Food: Colombo) Available at: www.waterandfood.org/research/basin-focal-projects/bfp-progress-reports.html (verified 10 June 2009).

Delgado C. , Rosegrant M. , and Meijer S. (2002). ‘Livestock to 2020: The Revolution Continues.’ (World Brahman Congress: Rockhampton.)

Delgado C. , Rosegrant M. , Steinfeld H. , Ehui S. , and Courbois C. (1999). ‘Livestock to 2020. The Next Food Revolution.’ Food, Agriculture and Environment Discussion Paper 28. (FAO: Rome.)

Etter L. (2007). Farm-production strains may keep food prices high. The Wall Street Journal, 6 November 2007.

FAO (Food and Agriculture Organization of the United Nations) (2009). FAOSTAT. Available at: http://faostat.fao.org/default.aspx (accessed 21 April 2009).

Fath B. D. (2004) Network analysis applied to large-scale cyber-ecosystems. Ecological Modelling 171, 329–337.
Crossref | GoogleScholarGoogle Scholar | (accessed 30 April 2009).

Kirby M. , Mainuddin M. , Ahmad M. , Gamage N. , Thomas M. , and Eastham J. (2009) ‘Water-Use Accounts in CPWF Basins: 4. Simple Water-Use Accounting of the Karkheh Basin.’ (In press). Available at: www.waterandfood.org

Kirby M. , Mainuddin M. , Ahmad M. , Marchand P. , and Zhang L. (2006). Water use account spreadsheets with examples of some major river basins. In: ‘9th International River Symposium, Brisbane’. Available at: www.riversymposium.com/index.php?page=2006 (accessed 18 May 2009).

Kirby M. , Mainuddin M. , and Eastham J. (2008). ‘Challenge Program Basin Water Use Accounts: 2. Model Concepts and Description.’ Draft Report. (Challenge Program on Water and Food: Colombo.)

Liu J., Williams J. R., Zehnder A. J. B., Yang H. (2007) GEPIC – modeling wheat yield and crop water productivity with high resolution on a global scale. Agricultural Systems 94, 478–493.
Crossref | GoogleScholarGoogle Scholar | (accessed 21 April 2009).

Peden D. , Tadesse G. , and Misra A. K. (2007). Water and livestock for human development. In: ‘Water for Food, Water for Life: Insights from the Comprehensive Assessment of Water Management in Agriculture’. (Ed. D. J. Molden.) pp. 485–514. (Earthscan Publications: London; IWMI: Colombo.)

Postel S. (2001) Growing more food with less water. Scientific American 284(2), 46.
PubMed |
(verified 16 May 2009).

Terrasson I., Fisher M. J., Andah W., Lemoalle J. (2009) Yields and water productivity of rainfed grain crops in the Volta Basin, West Africa. Water International 34, 104–118.
Crossref | GoogleScholarGoogle Scholar | (verified 16 May 2009).

World Bank (2007). ‘World Development Report 2008 – Agriculture for Development.’ (World Bank: Washington, DC.)

Zoebl D. (2006) Is water productivity a useful concept in agricultural water management? Agricultural Water Management 84, 265–273.
Crossref | GoogleScholarGoogle Scholar | open url image1