Water. Desalination + reuse
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Water. desalination + reuse June 2017 Far Site 25 'In an ideal world we will take fi ve years to scale up' RESEARCH BACKSTORY • Developments build on research fi rst published in Nature in 2012, demonstrating graphene oxide unique properties • In 2014, membrane swelling was identified as a barrier for desalination applications • Latest paper shows how 'physical confi nement' — an epoxy coating — can be used to prevent swelling "If everything goes to plan, my expectation is that we will have graphene oxide membranes in large scale production within the next ve years," says Rahul Nair, professor of materials physics and Royal Society university research fellow at the National Graphene Institute and School of Chemical Engineering and Analytical Science, at University of Manchester, UK. It's an ambitious timeline. But then Nair's research has progressed rapidly since his group rst published a paper on graphene oxide in Nature in 2012, demonstrating its unique properties that allow water to pass through but block larger molecules like solvents. "At the time, there was speculation about using this membrane for water ltration or desalination," says Nair. However in 2014, the next milestone paper demonstrated that salt in seawater in fact passed through the graphene oxide membrane with a cut-o‹ size of around one nanometre. "So that was no good for Nanotechnology in April 2017 is a proof of construct for a desalination application of a graphene oxide membrane, based on a laboratory setting and using saline water. The next step is to test the membranes with seawater, and in real-life applications. Next steps are to test with seawater and then to scale production "There are many experiments to carry out in future to compare our membrane with the state- of-the-art other membranes, and to show the real potential," says Nair. The team is in talks with commercial partners about potentially taking the programme to the next level. "We already know many end- users who want this membrane, and we want a partner with the engineering expertise who can make this into a large scale production. That's what we're looking at." He expects in two years' time to have more solid data comparing the graphene oxide membrane with existing market-leading membranes, and then another three years' work to scale production. "So, in an ideal case, we will take ve years," Nair concludes. desalination, but it was good for nano ltration applications," Nair adds. The challenge for the team at Manchester was that graphene- oxide membranes swell when immersed in water and that this enlargement of the pores enables sodium chloride to " ow through. From 2014, the group focused on tuning the sieve size, trying di‹ erent chemical and physical approaches, so that it would lter out common salts like sodium chloride. "It turned out that physical con nement was the best approach. We created a tuneable sieve. We put an epoxy coating on both sides of the membrane that prevents it from swelling, and so the sodium chloride cannot pass through," explains Nair. Their latest work, published in Nature Rahul Nair (right), professor of materials physics at the National Graphene Institute, UK, discusses the latest research with his joint-lead authors Jijo Abraham, PhD student (middle), and Dr Vasu Siddeswara Kalangi, research associate