A first-of-its-kind agrivoltaic pilot in Fujairah, developed as part of a joint research project between the Fujairah Research Center and AE Solar, shows how solar panels above native plants can improve soil health, boost crop resilience, and optimize land use – demonstrating a scalable approach to tackling a desert region’s energy, food, and water challenges.
Image: AE Solar
Agriculture in the United Arab Emirates (UAE) faces extreme challenges due to intense summer heat (>40 C), and persistent water scarcity. Across the Middle East and North Africa, nearly 90% of land is arid or semi-arid, making large-scale crop production difficult. At the same time, the region benefits from some of the world’s highest solar irradiation levels, offering strong potential for renewable energy.  However, large-scale solar farms – often the primary choice to tap this potential – compete with scarce arable land.
Arid regions like the UAE face simultaneous challenges in producing sufficient food, water, and electricity to meet their population’s needs. The solution lies in agrivoltaics, which integrates solar panels above crops to allow the same land to produce both food and energy. To test this approach in arid conditions, the Fujairah Research Centre – led by Dr. Fouad Lamghari Ridouane, in partnership with AE Solar, led by Dr. Hamed Hanifi, Director of Technology & Innovation – launched a pilot project. The initiative evaluated technical feasibility, agricultural productivity, and environmental impact, combining PV system modelling, agronomic monitoring, and microclimate analysis.
Installed in Al Fujairah City, the system features a 38.9 kWp PV array of 72 modules paired with a 320 kWh lithium-ion battery bank. A reinforced ground-mount structure was used instead of specialized agri-PV frames, reducing costs and improving scalability while maintaining uniform shading. High-temperature power electronics (>50 C rating) ensured reliable operation during peak summer, preventing derating losses typical in desert climates.
This project is the first documented agrivoltaic trial on native UAE plants, comparing growth under solar panels with open-field conditions. Plants were monitored in May and June 2025 for growth and physiological responses, while temperature, relative humidity, and photosynthetic photon flux density (PPFD) were recorded to understand microclimate effects. PPFD is a measurement in agriculture of how much “useful light” plants receive. Smart layouts and the right PV modules can reduce heat stress while keeping PPFD in the optimal range.
The results were striking. Under the solar panels, a unique microclimate emerged:
As a result, plants showed notable growth improvement:
This demonstrates that controlled shading from PV modules can enhance plant health, improve water retention, and boost crop resilience in arid climates, offering promising benefits for regional agriculture.
As the technology partner, AE Solar supplied the photovoltaic panels and provided technical expertise for the project’s design and implementation. The collaboration has transformed the Fujairah pilot from a research concept into a field-tested demonstration of agrivoltaic feasibility under harsh climatic conditions. Its agrivoltaic system offers a practical, scalable solution that meets the region’s growing energy, food, and water challenges all at once.
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