- Surplus electricity generated by these systems could serve other energy needs, aligning with SDG 7 (Affordable and Clean Energy).
- Reducing the irrigation gap with cost-effective solar pumps can boost food production and improve nutrition, contributing to SDG 2 (Zero Hunger).
A new study published in Environmental Research Letters has disclosed that standalone solar photovoltaic irrigation systems have the potential to meet more than a third of the water needs for crops in small-scale farms across sub-Saharan Africa.
In sub-Saharan Africa, 80% of agricultural production is from smallholder farmers, who face constraints on increasing farm productivity, resulting in a large yield gap. Extensive rain-fed agriculture and unpredictable and erratic rainfall are leading causes of low productivity and food insecurity in Africa, together with a low degree of mechanisation.
A new International Institute for Applied Systems Analysis- (IIASA) led the study as part of the research project Renewables for African Agriculture (RE4AFAGRI), an international team of researchers developed an open-source modelling framework that used various datasets related to agriculture, water, energy, expenses and infrastructure. This framework was employed to calculate local irrigation needs, determine the necessary size and cost of technology components like water pumps, solar PV modules, batteries, and irrigation systems, and assess the economic prospects and sustainable development impacts of adopting solar pumps.
“We estimate an average discounted investment requirement of US$3 billion per year, generating potential profits of over US$5 billion per year from increased yields to smallholder farmers, as well as significant food security and energy access co-benefits,” says Giacomo Falchetta, lead author of the study and a researcher in the Integrated Assessment and Climate Change Research Group of the IIASA Energy, Climate, and Environment Program. “Reducing the irrigation gap with cost-effective solar pumps can boost food production and improve nutrition, contributing to SDG 2 (Zero Hunger). Furthermore, surplus electricity generated by these systems could serve other energy needs, aligning with SDG 7 (Affordable and Clean Energy).”
The authors of the study also demonstrate the importance of business models and investment incentives, crop prices, and PV and battery costs in shaping the economic feasibility and profitability of solar irrigation.
“Using a business model that spreads out all initial expenses more than doubles the number of workable solar irrigation systems, presenting a huge potential to achieving the SDGs in the process,” notes IIASA Transformative Institutional and Social Solutions Research Group Leader Shonali Pachauri. “On the other hand, the study highlights that without strong land and water resource management infrastructure and governance, widespread deployment of solar pumps may drive unsustainable exploitation of water sources and reduce environmental flows. Consequently, investing in infrastructure, such as reservoirs for water management during seasonal variations, and enhancing water resource governance are critical factors for ensuring the sustainability of widespread solar pump deployment.”