Repellency of different liquids on polyester fabric coated with the short-chain polymer H1F7Ma-co-DVB: soy sauce (black drop), coffee (brown drop), hydrochloric acid (top left transparent drop), sodium hydroxide (bottom right transparent drop) and water (remaining transparent drops). Photo: Varanasi and Gleason research groups.Fabrics that resist water are essential for everything from rainwear to military tents, but conventional water-repellent coatings have been shown to persist in the environment and accumulate in our bodies, and so are likely to be phased out for safety reasons. That leaves a big gap to be filled if researchers can find safe substitutes.
Now, a team at Massachusetts Institute of Technology (MIT) has come up with a promising solution: a coating that not only adds water-repellency to natural fabrics such as cotton and silk, but is also more effective than existing coatings. The new findings are described in a paper in Advanced Functional Materials by MIT professors Kripa Varanasi and Karen Gleason, former MIT postdoc Dan Soto, and two others.
"The challenge has been driven by the environmental regulators" because of the phaseout of existing waterproofing chemicals, Varanasi explains. But it turns out his team's alternative actually outperforms the conventional materials.
"Most fabrics that say 'water-repellent' are actually water-resistant," says Varanasi, who is an associate professor of mechanical engineering. "If you're standing out in the rain, eventually water will get through." Ultimately, "the goal is to be repellent – to have the drops just bounce back." The new coating comes closer to that goal, he says.
Because of the way they accumulate in the environment and in body tissue, the US Environmental Protection Agency (EPA) is in the process of revising regulations on the long-chain polymers that have been the industry standard for decades. "They're everywhere and they don't degrade easily," Varanasi says.
The coatings currently used to make fabrics water repellent generally consist of long polymers with perfluorinated side-chains. Shorter-chain polymers that have been studied do not have as much of a water-repelling (or hydrophobic) effect as the longer-chain versions.
Another problem with existing coatings is that they are liquid-based, so the fabric has to be immersed in the liquid and then dried out. This tends to clog all the pores in the fabric, Varanasi says, so the fabrics can no longer breathe as they otherwise would. That requires a second manufacturing step in which air is blown through the fabric to reopen those pores, adding to the manufacturing cost and undoing some of the water protection.
Research has shown that polymers with fewer than eight perfluorinated carbon groups do not persist and bioaccumulate nearly as much as those with eight or more – the ones most in use. What the MIT team did, Varanasi explains, is to combine two things. One was a shorter-chain polymer that, by itself, confers some hydrophobic properties and has been enhanced with some extra chemical processing. The other was a different coating process, called initiated chemical vapor deposition (iCVD), developed in recent years by co-author Karen Gleason, a professor of chemical engineering, and her co-workers. According to Varanasi, credit for coming up with the best short-chain polymer and making it possible to deposit the polymer with iCVD goes primarily to Soto, who is the paper's lead author.
The iCVD coating process, which does not involve any liquids and can be done at low temperature, produces a very thin, uniform coating that follows the contours of the fibers and does not lead to any clogging of the pores. It thus eliminates the need for the second processing stage to reopen the pores. Finally, a kind of sandblasting of the surface can be added as an optional step to increase the water repellency even more. "The biggest challenge was finding the sweet spot where performance, durability and iCVD compatibility could work together and deliver the best performance," says Soto.
The process works on many different kinds of fabrics, Varanasi says, including cotton, nylon and linen, and even on non-fabric materials such as paper, opening up a variety of potential applications. The system has also been tested on different weave patterns of those fabrics. "Many fabrics can benefit from this technology," he says. "There's a lot of potential here."
The coated fabrics have been subjected to a barrage of tests in the lab, including a standard rain test used by industry. The materials have been bombarded not only with water but with various other liquids, including coffee, ketchup, sodium hydroxide, and various acids and bases – and have repelled all of them well.
The coated materials have been subjected to repeated washings with no degradation of the coatings, and have also passed severe abrasion tests, with no damage to the coatings after 10,000 repetitions. Eventually, under severe abrasion, "the fiber will be damaged, but the coating won't," Varanasi says.
The team plans to continue working on optimizing the chemical formula for the best possible water-repellency, and hopes to license the patent-pending technology to existing fabric and clothing companies.
This story is adapted from material from MIT, with editorial changes made by Materials Today. The views expressed in this article do not necessarily represent those of Elsevier. Link to original source.