Water-repellent coating hundreds of times more durable than others
A newly developed water-repellent coating, that it also self-healing, has been shown to be significantly more durable than its counterparts.
It is being positioned as a way to enable waterproofing of vehicles, clothing, rooftops and countless other surfaces for which current waterproofing treatments are too fragile.
It could also lower the resistance of ship hulls, a step that would reduce the fuel consumption of the massive vessels that transport 90 per cent of the world’s cargo.
The developer team at the University of Michigan claim it is hundreds of times more durable than other spray-on coatings and believes it is a breakthrough in a field where decades of research have failed to produce a durable coating.
While water-repellent finishes are currently available, they’re typically not strong enough for applications like clothing or ship hulls. This discovery changes that.
“Thousands of superhydrophobic surfaces have been looked at over the past 20 or 30 years, but nobody has been able to figure out how to systematically design one that’s durable,” said Anish Tuteja, the university's associate professor of materials science and engineering. “I think that’s what we’ve really accomplished here, and it’s going to open the door for other researchers to create cheaper, perhaps even better superhydrophobic coatings.”
The coating is made of a mix of a material called “fluorinated polyurethane elastomer” and a specialised water-repellent molecule known as “F-POSS”. It can be easily sprayed onto virtually any surface and has a slightly rubbery texture that makes it more resilient than its predecessors.
If it is damaged, the coating can heal itself hundreds of times. It can bounce back “even after being abraded, scratched, burned, plasma-cleaned, flattened, sonicated and chemically attacked”, the researchers wrote in a paper.
In addition to recovering physically, the coating can heal itself chemically. If water-repellent F-POSS molecules are scraped from the surface, new molecules will naturally migrate there to replace them. That’s how the coating can renew itself hundreds of times. Its healing ability is limited only by its thickness.
Lead author of the project Kevin Golovin said the team used a process that was radically different from previous research in the field.
“Most materials science researchers have focused on identifying one specific chemical system that’s as durable and water-repellent as possible,” he said. “We approached the problem differently, by measuring and mapping out the basic chemical properties that make a water-repellent coating durable. And some of the results surprised us.”
For example, most hydrophobic coatings are made of two main ingredients: an active molecule that provides the water-repellence and a binder. Generally, researchers have assumed that using more durable ingredients would make a more durable coating. But Tuteja’s team found that that’s not necessarily the case.
They discovered that even more important than durability is a property called “partial miscibility,” or the ability of two substances to partially mix together. The other key variable the team discovered is the stability of the water-repellent surface.
Most water-repellent coatings work because their surface has a very specific geometry, often microscopic pillars. Water droplets perch on the tips of these pillars, creating air pockets underneath that deny the water a solid place to rest and cause it to roll off easily. But such surfaces tend to be fragile – slight abrasion or even the pressure of the water itself can damage them.
The team’s research found that a surface that’s slightly pliable can escape this pitfall – even though it seems less durable, its pliable properties enable it to bounce back from damage.
Tuteja estimates that the coatings will be available for use before the end of 2017 for applications including water-repellent fabrics and spray-on coatings that can be purchased directly by consumers.
A self-healing polymer was recently revealed by a team of US scientists that could be the perfect candidate material for a self-healing mobile phone screen or battery.