Abstract
Flood-based farming systems (FBFS) are extensively used throughout Sub-Saharan Africa. Consisting of spate irrigation, flood recession and flood rise farming, inundation canals and depression agriculture, it is estimated that these farming systems cover close to 25 million hectares in this region alone. For each of these FBFS, different techniques and approaches can be used to develop their potential. A wide variety of best practices can be captured from around the world that are instrumental to strengthen FBFS. Significant gains can be made in the area of water distribution, field water management, groundwater use, agronomic practices, multi-functional use of floodplains as well as their governance. Thus, this chapter discusses the effect of FBFS on sedimentation processes and soil fertility, the link between the distribution and management of both floodwater and run-off and the different ecosystem services: water for agriculture, rangeland management, drinking water and recharge. There is a need to take an integrated approach towards FBFS development by promoting multi-functionality, including making use of the agricultural potential. Changes needed to come to a sustainable multi-functionality are often not complex or costly but require good understanding of the local resource base, its carrying capacity and insights into opportunities for improvement.
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References
Chidumayo E.N. (1992). The utilization and status of dambos in Southern Africa: a Zambian case study. In Wetlands Conservation Conference for Southern Africa. International Union for Conservation of Nature (IUCN). Gland, Switzerland.
Comprehensive Assessment of Water Management in Agriculture (CAWMA) (2007). Water for Food, Water for Life: A Comprehensive Assessment of Water Management in Agriculture. Earthscan, London, U.K and International Water Management Institute, Colombo, Sri Lanka.
FAO (1997) Irrigation potential in Africa; a basin approach. Food and Agriculture Organisation of the United Nations, Rome, Italy. Accessible at: http://www.fao.org/docrep/W4347E/W4347E00.htm. Retrieved on 4th July 2016.
Garcia-Landarte Puertas D., Van Steenbergen F., Mehari A., Kool M., Gebreegziabher T.A. (2014). Flood Based Farming Systems in Africa. Overview Paper 5. Spate Irrigation Network, MetaMeta, Wageningen, The Netherlands.
Gumma M.K., Pavelic P. (2013). Mapping of groundwater potential zones across Ghana using remote sensing, geographic information systems, and spatial modelling. Environmental Monitoring and Assessment, 185(4): 3561–3579.
Hollis G.E., Adams W.M., Aminu Kaino M. (1993). The Hadejia-Nguru Wetlands: Environment, Economy and Sustainable Development of a Sahelian Floodplain Wetlands. International Union for Conservation of Nature (IUCN), Gland, Switzerland.
Knoop L., Sambalino F., van Steenbergen F. (2012). Securing water and land in the Tana basin: a resource book for water managers and practitioners. MetaMeta Research, Wageningen, The Netherlands.
Maar A., Mortimer M.A.E, van der Lingen I. (1966). Fish culture in Central East Africa. Food and Agriculture Organisation of the United Nations, Rome, Italy.
Ofosu E.A. (2011). Sustainable Irrigation Development in the White Volta sub-Basin. UNESCO-IHE PhD Thesis. CRC Press, The Netherlands.
Olley J. (2008). Human-Powered Handpumps for Water Lifting. Practical Action, Rugby, U.K.
Tien P.D., Ni D.V. (2014). A Wise Use of Flood Water Resource at The Mekong Delta of Vietnam. Overview Paper 11. Spate Irrigation Network, MetaMeta, Wageningen, The Netherlands.
Turner B. (1986). The importance of Dambos in African Agriculture. Land Use Policy, 343–347.
Van Daam A.A, Kaggwa R.C., Kipkemboi J. (2006). Integrated pond aquaculture in Lake Victoria Wetlands. In: Integrated irrigation and aquaculture in West Africa: concepts, practices and potential, 129–134. Food and Agriculture Organisation of the United Nations, Rome, Italy.
Van Steenbergen F., Mehari A. (2009). Spate irrigation: Good for People, Livestock and Crops. Leisa, 25(1): 32.
Van Steenbergen F., Lawrence P., Mehari A., Salman M., Faures J. (2010). Guidelines on spate irrigation. Irrigation and drainage paper 65. Food and Agriculture Organisation of the United Nations, Rome, Italy.
Wester P., Bron J. (1998). Coping with water: Water Management in Flood Control and Drainage Systems in Bangladesh. International Livestock Research Institute, Wageningen, The Netherlands.
Zwarts L., van Beukering P., Kone B., Wymenga E. (2005). The Niger, a lifeline. Effective Water Management in the Upper Niger Basin. RIZA, Lelystad, The Netherlands.
Acknowledgements
The authors wish to express their gratitude for the support provided by the Harnessing Floods to Enhance Livelihoods and Ecosystems Services project, under the CGIAR Water, Land and Ecosystems program and the Africa to Asia and Back Again: Testing Adaptation for Flood-Based Farming Systems program, supported by IFAD and EU, for preparation of this chapter.
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Kool, M., van Steenbergen, F., Mehari Haile, A., Abbas, Y.M., Hagos, E. (2018). The Promise of Flood-Based Farming Systems in Arid and Semi-arid Areas. In: Leal Filho, W., de Trincheria Gomez, J. (eds) Rainwater-Smart Agriculture in Arid and Semi-Arid Areas. Springer, Cham. https://doi.org/10.1007/978-3-319-66239-8_5
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