Latest news with #hydrogel
Fast Company
30-06-2025
- Science
- Fast Company
New MIT tech turns desert air into safe drinking water
An innovative and potentially impactful new device can turn air into drinkable water, even in the driest climates. The tool, which comes from researchers at MIT, could be a huge step towards making safe drinking water worldwide a reality. Lack thereof impacts 2.2 billion people, per a study on the invention, which was recently published in journal Nature Water. The device was developed by Professor Xuanhe Zhao, the Uncas and Helen Whitaker Professor of Mechanical Engineering and Civil and Environmental Engineering at MIT, and his colleagues. According to the study, the contraption is made from hydrogel, a material that absorbs water, and lithium salts that can store water molecules. The substance is enclosed between two layers of glass, and at night, pulls water vapor from the atmosphere. During the day, the water condenses and drips into tubes. It's is about the size of a standard window, but even in environments that are hot and dry, it's able to capture water. Zhao's team tested the tool in the driest environment in the U.S. — Death Valley, California. Even in the ultra-dry conditions, the tool was able to capture 160 milliliters per day (about two-thirds of a cup). The success of the model has the scientists thinking on a bigger scale. 'We have built a meter-scale device that we hope to deploy in resource-limited regions, where even a solar cell is not very accessible,' says Xuanhe Zhao, per MIT News. Zhao continued, 'It's a test of feasibility in scaling up this water harvesting technology. Now people can build it even larger, or make it into parallel panels, to supply drinking water to people and achieve real impact.' The new design addresses several issues that past similar devices have come up against. It's better at absorbing water than metal-organic frameworks (MOFs) that can also capture water from air. The new design, which has a sophisticated composition and added materials, is also better at limiting salt leakage. During the experiment, that meant that the water collected met criteria for safe drinking water. 'We imagine that you could one day deploy an array of these panels, and the footprint is very small because they are all vertical,' says Zhao. 'Then you could have many panels together, collecting water all the time, at household scale.'
Yahoo
29-06-2025
- Science
- Yahoo
MIT's high-tech ‘bubble wrap' turns air into safe drinking water — even in Death Valley
When you buy through links on our articles, Future and its syndication partners may earn a commission. MIT researchers have created a high-tech 'bubble wrap' capable of collecting safe drinking water directly from the air — even in Death Valley, the driest desert in North America. The new water harvester is a major step towards providing safe, accessible drinking water to people across the globe — and works wherever you may find water vapor in the air, scientists said in a new study published June 11 in the journal Nature Water. The water harvester is made from hydrogel (a highly water-absorbent material) that is enclosed between two layers of glass — much like a window. At night, the device absorbs water vapor from the atmosphere. During the day, the water condenses on the glass thanks to a coating that keeps the glass cool. The liquid water then drips down the glass and is collected in a system of tubes. The hydrogel is formed into a special shape, a series of domes resembling a sheet of bubble wrap that swells up when absorbing water vapor. The domes increase the material's surface area, which increases the amount of water it can hold. Researchers tested the new device for a week in Death Valley, a unique desert valley spanning across parts of California and Nevada. It's the hottest place in the world and the driest place in North America. Related: 2 billion people could face chaotic and 'irreversible' shift in rainfall patterns if warming continues It produced about a quarter to two-thirds of a cup of water every day (57-161.5 milliliters). In more humid areas, the device should produce even more water. This design is a lot more effective than some previous attempts to collect drinking water from air, all without needing electricity to power it, MIT representatives said in a statement. The researchers also solved another long-standing problem with the quality of water collected using hydrogel designs. Lithium salts, added to the hydrogel to increase water absorption, normally leak into the water in similar designs, rendering the water unsafe to drink without further processing. This new design includes a salt stabilizer called glycerol which reduces the leakage below 0.06 ppm, the US Geological Survey's estimate for how much lithium salt can be present in groundwater before it might be unsafe to drink. RELATED STORIES —Stabbed, cut, attacked, twisted — scientists subject new stretchable battery to extreme torture, and it retained 90% of its capacity —Ancient groundwater records reveal worrying forecast for US Southwest —Scientists invent photosynthetic 'living' material that sucks CO2 out of the atmosphere While one panel might not produce enough water to sustain an entire household, they don't take up much space — which means multiple panels could be set up for a single household. The researchers estimate that using eight 3 foot by 6 foot (1 m by 2 m) panels could be enough to supply households anywhere that there isn't easy access to safe drinking water. Compared to the costs of bottled water in the US, the device could pay for itself in less than a month and last at least one year. 'We imagine that you could one day deploy an array of these panels, and the footprint is very small because they are all vertical,' Xuanhe Zhao, one of the paper's authors and a professor of both MIT's mechanical engineering and civil and environmental engineering departments, said in the statement. 'Now people can build it even larger, or make it into parallel panels, to supply drinking water to people and achieve real impact.' The team plans to test the panels in additional resource-limited environments to learn more about the device's performance under different conditions.
