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Optimizing Agricultural Land Use: Five Insights on Agrivoltaics

Five facts on how agrivoltaics works and boost resilience

Agrivoltaics (AV) is an innovative Water-Energy-Food Nexus approach that increases land-use efficiency through the combination of solar energy generation with agricultural production. In simple terms, solar panels are placed on an elevated structure, allowing for space for agricultural activities beneath.

The concept was pioneered in Germany in 1982, and since then AV has been recognized as a strategy for minimizing the impacts of solar panel installations on land. The Pan African Cooperation and Educational Technologies (PACET) division of UNU-VIE is leading the APV-MaGa project in establishing four AV demonstrators in farms in Mali and The Gambia, which face severe challenges due to climate change.

Here are five insights on how it works and how AV can be a boost for resilience:

  1. An Agrivoltaic system can make crop production more resilient to crop failure and climate change

    With proper design and modelling, an AV system can lower plant and crop temperatures and reduce evaporation and transpiration, the processes of moisture leaving soil and vegetation. Furthermore, a unique benefit is that a microclimate can be created under the panels, which can help crop growth and production

  2. Agrivoltaics can be a catalyst for development and land-use efficiency

    AV systems can spur development in communities, potentially bringing electricity and services such as water pumping, food processing and cold storage for food preservation. An AV system can be upgraded with a rainwater harvesting system, which promotes a “triple land-use” approach that can reduce the total space needed for food, water and energy production.

  3. Agrivoltaics can be best utilized in places facing increasing temperatures, water scarcity and a lack of energy supply

    Agricultural fields in regions which face increasing temperatures, receive high solar irradiance and are prone to water scarcity can benefit from the partial shading provided by the panels, potentially increasing their yield. At the same time, panels can be used for rainwater harvesting, increasing water availability. Additionally, the technology can be very helpful in places where space is already limited, or where a decentralized energy system is the only option to access energy.

  4. To be successful installations must be designed closely with communities to address their needs and interests

    While agrivoltaics offers numerous benefits, its implementation still faces challenges due to a necessary paradigm shift and the need for widespread acceptance prior to installation. As a relatively new technology and approach, it can face some resistance. This is particularly a challenge in low-income countries where social acceptance, capacity-building and a close working relationship with the beneficiary community and local stakeholders are key for the successful and sustainable installation of an AV system.

  5. Agrivoltaic systems can potentially improve and create socioeconomic opportunities through the implementation of sustainable business models

    Socioeconomic opportunities include the creation of business models around the productive uses of energy, such as water pumping, food processing and cold storage. Therefore, AV systems must be tailor-made for desired activities, certain settings and crop types. With profits, the costs associated with maintenance and repairs can be covered, increasing the sustainability of the installation, agricultural activities, and the livelihoods of communities.

Learn more about the APV-MaGa project here.