Enhancing farming system water productivity through alternative land use and improved water management of rainfed agriculture in Vertisol areas

Waterlogged Vertisols are amongst the high potential soils where management interventions could result in positive impacts. This study utilized soil, climate and crop and livestock productivity data and models to demonstrate intensification strategies which increase crop–livestock system productivity and to understand the effects of alternative land use and water management options on water productivity in the Vertisols areas. The areas have been classified into three slope classes including areas where artificial drainage is not feasible, where Broad Bed and Furrows (BBF) can be used to drain the excess water and naturally drained areas, represented by areas with 0–2%, 2–5% and over 5% slope steepness, respectively. Early planting of wheat (Triticum spp) using BBF on drainable areas and rice (Oryza sativa) or grasspea (Lathyrus sativus) on the flat areas were compared with the traditional practices. Yield and biomass data were obtained from research stations in the area whilst the effective rainfall and crop water requirement were estimated using CROPWAT Model. The feed value of the native grass and crop straw was estimated based on previous works. With respect to effective rainfall, the water productivity increase due to BBF over the control ranged from 5 to 200%, with an average increase of 57%. Despite higher water consumption of the rice, feeding its residues to livestock enhanced the overall economic water productivity of the system over the natural grazing or grasspea cultivation. Consequently, use of BBF enables growing high value or food crops of choice that may be sensitive to waterlogging whilst tolerant crops can be grown on flat lands allowing utilization of the full growing period. Coupled with livestock integration into the system, the alternatives can enhance food production and resource use efficiency from these ‘marginal’ areas

Livestock and water interactions in mixed crop-livestock farming systems of sub-Saharan Africa: interventions for improved productivity

In sub-Saharan Africa (SSA), the increasing competition for water between various sectors is aggravated by growing demands for water, climate change and environmental degradation. One of the major consumers of water is livestock keeping, which is an important livelihood strategy for smallholder farmers in Africa. The water consumption for livestock production is currently increasing with the growing demands for livestock products. On the other hand, current low returns from livestock, limit its contribution to livelihoods, threaten environmental health and aggravate local conflicts. The objectives of this review are to (1) bring together the available knowledge in the various components of the livestock and water sectors, (2) identify promising strategies and interventions to improve the situation using the “livestock water productivity” (LWP) concept, and (3) identify critical research and development gaps. Improvements in LWP can lead to a positive impact on poverty reduction, resilience and environmental health, provided that interventions are well-targeted, community innovation and empowerment is achieved and appropriate dissemination and communication lead to awareness and adoption. Promising interventions are grouped in two domains. In the biophysical domain, numerous interventions related to feed, water and animal management can be applied to increase LWP. These should be complemented and integrated with interventions in the socio-political-economic domain. Enhancing the capacity of local institutions, improving market incentives and facilitating socioeconomic arrangements form part of the institutional improvements. A conducive policy framework, taking into account equity and gender and geared towards problem-solving local policies, improvements in infrastructure, price signals and land tenure systems, is a prerequisite for the successful application of the LWP concept. However, for the LWP concept to be widely applicable, knowledge gaps have to be filled, in terms of methodologies for quantifying water productivity and integrating animal, herd, farm, water catchment and basin scales. This paper suggests approaches for the integration of technological, policy and institutional interventions that would contribute to making the LWP concept operational