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Earth Science and Engineering

Harnessing the sun’s energy for rainfall

Simulations show that solar panel installations could go a long way toward addressing Saudi Arabia’s growing water crisis.

(From left) Professor Georgiy Stenchikov, Suleiman Mostamandi and Sagar Parajuli developed a weather forecasting model that can simulate the impact of installing solar panels on local rainfall along the Red Sea coast of Saudi Arabia. Their simulations predict that the solar panels could ultimately increase rainfall in this arid region. © 2022 KAUST; Anastasia Serin.

KAUST researchers describe a method that could harness water evaporated from the Red Sea by converting it into increased rainfall. © 2022 KAUST; Anastasia Serin. https://discovery.kaust.edu.sa/en/article/1218/harnessing-the-sun's-energy-for-rainfall

KAUST researchers describe a method that could harness water evaporated from the Red Sea by converting it into increased rainfall. © 2022 KAUST; Anastasia Serin. https://discovery.kaust.edu.sa/en/article/1218/harnessing-the-sun’s-energy-for-rainfall

Installing solar panels along a part of Saudi Arabia’s west coast could generate enough rainwater to meet the annual consumption needs of five million people. An international team developed a weather forecasting model and tested it using simulations conducted on KAUST’s supercomputer Shaheen II. Saudi Arabia is in the midst of a water crisis. The Kingdom is experiencing increasing water demand as its population grows and industrial and agricultural activities intensify. At the same time, the country’s 9,000-year-old fossil groundwater from deep aquifers is rapidly depleting, while its already small amount of annual rainfall is decreasing in most regions. Still, at 300 tons per year, Saudi Arabia has one of the highest per capita rates of water consumption in the world. Desalinating and treating water provide two gigatons of water annually; however, both processes are energy intensive and are unable to meet the country’s rising water demands.

The solar panels along the coast decrease the surface albedo, warming the land and increasing the temperature contrast with the colder ocean. This intensifies sea breezes and transports more water vapor inland, ultimately increasing rainfall.

 The solar panels along the coast decrease the surface albedo, warming the land and increasing the temperature contrast with the colder ocean. This intensifies sea breezes and transports more water vapor inland, ultimately increasing rainfall. 

© 2022 KAUST; Ivan Gromicho. 

Led by KAUST’s Georgiy Stenchikov, the team aimed to find out if deliberate changes to a 150 x 103 km2 area of Saudi Arabia’s west coast could increase rainfall in the region by harnessing the two meters of water that evaporate from the Red Sea every year. The team of scientists from Saudi Arabia, Germany, France and Russia configured a weather forecasting model to suit their region of interest. They then ran simulations on KAUST’s Shaheen II computer that incorporated already known data on sea and land surface temperatures, winds, land topography and rainfall with scenarios in which various land features like forestation, soil moisture and surface reflection of the sun’s energy were changed. “Our study showed that decreasing the fraction of sunlight reflected by the Earth’s surface — known as the land surface albedo — warmed the land, increasing the temperature contrast between it and the colder ocean,” explains KAUST meteorologist Suleiman Mostamandi. “This strengthened the sea breeze, which in turn carried more water vapor inland, increasing rainfall.” Importantly, the team showed that the surface albedo could be adequately reduced by installing solar panels along a part of Saudi Arabia’s western coastal plain, generating 1.5 gigatons of extra rainwater each year. “Solar panels would absorb more solar radiation than natural land cover, ultimately triggering rainfall,” explains Mostamandi. Notably, Saudi Arabia already has a network of artificial water reservoirs that could be augmented for collecting and storing the increased rainwater. Further field experiments will be needed to provide the proof of concept. The simulations also showed that increasing forestation in the Red Sea coastal area did not effectively trigger rainfall. This finding highlights the need for a thorough evaluation of the environmental effects of the planned large-scale greening projects in Saudi Arabia and the Middle East.

References

  1. Mostamandi, S., Predybaylo, E., Osipov, S., Zolina, O., Gulev, S., Parajuli, S.& Stenchikov, G. Sea breeze geoengineering to increase rainfall over the Arabian Red Sea coastal plains. Journal of Hydrometeorology 23, 3-24 (2022).| article
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