Floating solar photovoltaic systems on global reservoirs hold great potential for enormous energy production and water savings
Growing global energy use and the adoption of sustainability goals to limit carbon emissions from fossil fuel burning are increasing the demand for clean energy, including solar. Floating photovoltaic (FPV) systems on reservoirs are advantageous over traditional ground-mounted solar systems in terms of land conservation, efficiency improvement, and water loss reduction.
The key advantages of FPV systems installed on existing reservoirs are that they preserve land for other uses, and most reservoirs tend to be located in proximity to existing grid systems. Furthermore, the cooling effect of water in some installations enhances energy conversion efficiencies, and FPV panels/floats reduce reservoir water losses from evaporation by blocking radiative energy and lowering water temperatures. As large-scale renewable energy application is still in its infancy in most of the world, accurate estimates of the global technical potential of FPV are needed to frame discussions on its potential role within diversified energy portfolios as countries strive to decarbonize.
Based on multiple reservoir databases and a realistic climate-driven photovoltaic system simulation, Associate Professor Zhenzhong Zeng’s research team from the School of Environmental Science and Engineering at the Southern University of Science and Technology (SUSTech) recently estimated that the technical potential electricity generation for FPV systems with a 30% coverage on 114,555 global reservoirs is 9,434 ± 29 TWh yr-1.
Also beneficial to FPV worldwide is that the reduced annual evaporation could conserve 106 ± 1 km3 of water, almost the average amount of water 300 million people uses annually. FPV systems on reservoirs could potentially be utilized to improve water and energy security as a part of achieving sustainable development goals.
Their study, entitled “Energy production and water savings from floating solar photovoltaics on global reservoirs,” has been published in Nature Sustainability.
The researchers took advantage of recent advances in the compilation of data on existing reservoirs worldwide and a reliable climate-driven PV system performance model to assess with fine precision the annual generation potential for FPV ranging from 4,300 to 11,000 TWh under different coverages on a global scale. Under the assumption of 30% coverage and not exceeding 30 km2, the United States, with more than 25,000 reservoirs, has the largest FPV potential (1,911 ± 18 TWh yr-1), which per unit area is 177 ± 2 kWh m-2 yr-1. China, which leads the world in total FPV installed capacity, ranks second with 1,107 ± 17 TWh of annual electricity generation potential on 15,616 reservoirs.
Figure 1. Global potential for annual floating photovoltaic (FPV) generation with 30% reservoir coverage (not exceeding 30 km2).
One of the benefits of FPV is the tendency of resources to be close to centers of high electricity consumption. Thus, FPV would be appropriate for cities/communities with a desire to generate their own electricity through dedicated systems to compete with large power providers and stimulate local economies. Moreover, isolated power systems such as microgrids based on FPV could provide resilient, local, and affordable power in remote areas where grid infrastructure is deficient. The researchers found that 6,256 cities in 124 countries, including 154 metropolises, could, in theory, be powered entirely by local, dedicated FPV plants assuming that adequate energy storage facilities can be developed in tandem.
Figure 2. Comparison of floating photovoltaic (FPV) generation potential and electricity demand in cities with 30% reservoir coverage (not exceeding 30 km2).
Regarding water body evaporative losses, Prof. Zeng’s team estimated that FPV systems with 30% coverage could reduce evaporation by 46 ± 3% per reservoir. On the assumption that the floats below the FPV modules cover the surface entirely, water evaporation under an FPV installation approaches zero and evaporation on the surrounding uncovered water surface is also reduced because of the changes to reservoir energy balance variables. They estimate the evaporation loss reduction worldwide is equivalent to 106 ± 1 km3 per year, which is close to that used by 300 million people annually.
Figure 3. Estimated global water savings from floating photovoltaic (FPV) development with 30% reservoir coverage (not exceeding 30 km2).
Yubin Jin, a master’s student from the School of Environmental Science and Engineering at SUSTech, is the first author of this paper. Assoc. Prof. Zhenzhong Zeng is the corresponding author. Other affiliations that contributed to this work include ETH Zurich, Mae Jo University, University of California, Santa Cruz (UCSC), University of Gothenburg, University of Michigan, and MingYang Smart Energy.
This study was supported by the National Natural Science Foundation of China (NSFC) and the Start-Up Fund provided by SUSTech.
Paper link: https://www.nature.com/articles/s41893-023-01089-6