This sustainable technique can create nearly 40 gallons of clean drinking water per cycle.
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This at-risk population is expected to grow over the next five-years as the climate crisis creates more and more water-stressed areas, according to the World Health Organization (WHO.)
Scientists have been working to solve this problem for decades, and while some solutions have found success in effectively cleaning water, those energy-heavy solutions can be hard to implement in communities without a stable electric grid.
Now, a team of scientists from Australia and China has proposed a sustainable solution that relies on sunlight to jump-start the filtration process instead of heat or electricity.
Using a super porous material to suck up salt from brackish, salty water, researchers were able to sustainably create nearly 40 gallons of clean drinking water per single kilogram of a metal material. Better yet, this drinking water was even cleaner than WHO's official guidelines.
This finding was published Monday in the journal Nature Sustainability.
"Sunlight is the most abundant and renewable source of energy on Earth."The study's lead author Huanting Wang, a professor of chemical engineering at Monash University in Australia, says that his team's approach makes use of the planet's most abundant resource: sunlight. Their solar-powered method desalinates brackish, or stagnate, water more sustainable than previous methods.
"[T]hermal desalination processes by evaporation are energy-intensive, and other technologies, such as reverse osmosis, has a number of drawbacks, including high energy consumption and chemical usage in membrane cleaning and dechlorination," Wang says. "Sunlight is the most abundant and renewable source of energy on Earth."
Wang and his colleagues explain in the study that a sustainable energy source, like sunlight, would be especially useful for communities that may not have access to a reliable electric grid necessary for other methods of desalination.
Using darkness as well as visible light, researchers can coax this special material into absorbing salt from water at incredibly fast speeds. Nature Sustainability |
Because of its unique crystalline structure, this compound is incredibly porous, with so many nooks and crevices within it that its overall surface area is actually the largest per unit measure of any known material.
So large in fact, that scientists estimate the entire area of a football field could fit within a single teaspoon of this material. A characteristic that makes it really effective at sucking up salt from water.
The researchers further enhanced the absorption of this material by adding another material to its pores, called PSP-MIL-53. This material is characterized by having "breathing effects," and is able to promote efficient absorption.
After testing this material on both natural saltwater and synthetic saltwater, they found that the compound was able to absorb enough water in 30 minutes to create nearly 40 gallons of fresh drinking water per single kilogram of the material.
When analyzing the resultant water, the researchers measured its total dissolved solids (TDS) to be less than 500 parts per million — a standard even above that recommended by WHO, which categorizes clean drinking water as having TDS no greater than 600 parts per million.
The initial absorption is done in the dark but a four-minute exposure to sunlight causes the material to release its collected salt and begin the absorption process again for many more cycles.
"This study has successfully demonstrated that the photoresponsive [metal compounds] are a promising, energy-efficient, and sustainable adsorbent for desalination," said Wang. "Our work provides an exciting new route for the design of functional materials for using solar energy to reduce the energy demand and improve the sustainability of water desalination."
What's next — In addition to helping provide a sustainable solution to creating clean drinking water for communities with poor energy infrastructure, the researchers also say that this approach could be repurposed in the future for the absorption of other compounds and minerals, creating a sustainable solution for mineral mining as well. What has to happen next is determining how to get this tech out of the lab, and into the field.
Links
- A sunlight-responsive metal–organic framework system for sustainable water desalination
- Breakthrough technology purifies water using the power of sunlight
- Water breakthrough: Device uses solar power to produce clean water - and electricity
- 2.1 billion people lack safe drinking water at home, more than twice as many lack safe sanitation
- Environmental and social determinants of health
- Drinking-water
- Guidelines for drinking-water quality
- Solar Energy
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