Scientists Develop New Solar Device That Squeezes Water From Air

A new sponge-like material uses sunlight to harvest water from air, offering an efficient, low-cost solution for water scarcity.

Engineers from Australia and China have developed a sponge-like device that captures moisture from the air and releases it into a cup using solar energy. Unlike other technologies such as fog harvesting and radiative cooling, this device remains effective even in low-humidity conditions.

The water-harvesting system performs reliably across a wide range of humidity levels, from 30 to 90 percent, and temperatures between 5 and 55 degrees Celsius.

According to senior researcher Dr Derek Hao from RMIT University in Melbourne, the device uses the naturally porous structure of refined balsa wood, which has been modified to absorb atmospheric moisture and release it when needed.

The team’s wood-based composite fits neatly inside a cup, which includes a dome lid, an anti-pollution tray, a cooling system, and a solar-powered activation mechanism.

“Billions of people around the world lack access to drinkable water, and millions die from water-borne diseases every year,” said Hao, a materials scientist and environmental engineer in RMIT’s School of Science.

Hao was corresponding author on the study, which was done in collaboration with five Chinese research institutions, led by Dr Junfeng Hou from Zhejiang A&F University.

“Our team has invented a device comprising wood’s spongy scaffolding, lithium chloride, iron oxide nanoparticles, a carbon nanotube layer, and other specialized features,” Hao said.

The team used artificial intelligence for accurate prediction and optimization of the device’s water harvesting and discharging performance under varying environmental conditions.

Watershed moment

The spongy material, which is an early-stage lab prototype, absorbs moisture from the atmosphere when the cup’s lid is open. When the lid is closed under sunlight, water is released into the cup.

Under laboratory conditions, the water-from-air device absorbed about 2 milliliters of water per gram of material at 90% relative humidity and released nearly all the water within 10 hours under sun exposure – higher than most other known methods and at less cost. With nine sponge cubes, each weighing 0.8 grams, 15 milliliters of water can be absorbed and released into the cup.

“In outdoor tests, our device captured 2.5 milliliters of water per gram overnight and released most of it during the day, achieving a daily water collection efficiency of 94%,” Hou said.

“At 30% humidity, our device absorbed water at about 0.6 milliliters per gram. These results highlight its potential use in off-grid, solar-driven water harvesting systems.”

Benefits of the nature-inspired design

Hao said the use of natural wood as a matrix not only reduced costs but also provided structural integrity and enhanced water transport through its porous architecture.

“These features enable the material to be manufactured in large quantities and deployed in real-world applications such as water collection in remote or arid regions,” he said.

“The device retained its flexibility and water-absorbing function even after being stored at −20 degrees Celsius for 20 days, demonstrating excellent freeze resistance. Its moisture absorption–release performance was stable across 10 consecutive cycles, with less than 12% decline in efficiency.”

Potential applications and scalability

Hao said the device would be suited to emergency scenarios, such as in the wake of natural disasters where water supplies have been compromised, if the team can scale-up and optimise the modular innovation.

“The current demonstration unit size is 15 cubic millimeters. It would be very easy to prepare a larger unit, or we can use the units to form an array,” Hao said.

“Its ability to harvest potable water from the atmosphere using only sunlight makes it invaluable in disaster-stricken areas where traditional water sources are compromised. The system’s portability and reliance on renewable energy further enhance its applicability in such contexts.”

Hao said the material was designed with scalability and affordability in mind.

“The main component, balsa wood, is widely available, biodegradable, and cheap, and the manufacturing process is not complex, which could enable mass production. ​ The demonstrated stable performance over multiple cycles and in various environmental conditions indicates longevity and cost-effectiveness.”

Hao said the team was in discussion with prospective industry partners on pilot-scale production and field deployment, integration into modular water-from-air harvesting systems.

“Solar panels combined with thermal energy storage could enable round-the-clock operation, particularly in areas with intermittent sunlight,” he said.

Developing automated control systems using Internet of Things sensors to monitor relative humidity, temperature, and solar intensity could further optimise water harvesting cycles, Hao said.

“Building on the artificially intelligent design used in the study, more advanced design platforms could be developed to screen new material combinations and predict long-term water absorption and release performance,” he said.

Reference: “Development and characterization of novel wood-based composite materials for solar-powered atmospheric water harvesting: A machine intelligence supported approach” by Xingying Zhang, Yangyang Xu, Shenjie Han, Xiang Weng, Wenbo Che, Kongjie Gu, Ying Guan, Youming Yu, Derek Hao and Junfeng Hou, 28 February 2025, Journal of Cleaner Production.
DOI: 10.1016/j.jclepro.2025.145061

Funding: National Natural Science Foundation of China

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