This is a photo of the Namib Desert Beetle, whose bumpy shell inspired the development of a novel surface that can control the growth of frost caused by condensation. Photo: Wikimedia Commons.
This is a photo of the Namib Desert Beetle, whose bumpy shell inspired the development of a novel surface that can control the growth of frost caused by condensation. Photo: Wikimedia Commons.

In a discovery that may lead to new ways to prevent frost on airplane parts, condenser coils and even windshields, a team of researchers has used chemical micropatterns to control the growth of frost caused by condensation. Writing in Scientific Reports, the researchers describe how they used photolithography to pattern chemical arrays that attract water on a surface that repels water, thereby controlling or preventing the spread of frost.

The inspiration for the work came from an unlikely source, the Namib Desert Beetle, which lives in one of the hottest places in the world but is still able to collect airborne water. The insect has a bumpy shell and the tips of the bumps attract moisture to form drops, but the regions between the bumps are smooth and repel water, creating channels that lead directly to the beetle's mouth.

"I appreciate the irony of how an insect that lives in a hot, dry desert inspired us to make a discovery about frost," said Jonathan Boreyko, an assistant professor of biomedical engineering and mechanics at the Virginia Tech College of Engineering. "The main takeaway from the Desert Beetle is we can control where dew drops grow."

Working at the Oak Ridge National Laboratory, the researchers developed their beetle-inspired, frost-controlling chemical pattern on a surface with an area of just 1cm2.But they believe the same approach can be scaled up to produce large surface areas with thirsty, hydrophilic patterns overlaid on top of a hydrophobic, or water-repellant, surface.

"We made a single dry zone around a piece of ice," Boreyko said. "Dew drops preferentially grow on the array of hydrophilic dots. When the dots are spaced far enough apart and one of the drops freezes into ice, the ice is no longer able to spread frost to the neighboring drops because they are too far away. Instead, the drops actually evaporate completely, creating a dry zone around the ice."

Creating frost-free zones on larger surfaces could have a variety of applications, helping to prevent water from freezing on heat pump coils, wind turbines and airplane wings. "Keeping things dry requires huge energy expenditures," said C. Patrick Collier, a research scientist at the Nanofabrication Research Laboratory Center for Nanophase Materials Sciences at Oak Ridge National Laboratory and a co-author of the study. "That's why we are paying more attention to ways to control water condensation and freezing. It could result in huge cost savings."

The journey of frost across a surface begins with a single, frozen dew drop, the researchers said. "The twist is how ice bridges grow," Boreyko said. "Ice harvests water from dew drops and this causes ice bridges to propagate frost across the droplets on the surface. Only a single droplet has to freeze to get this chain reaction started."

By controlling the spacing of the condensation, the researchers were able to control the speed at which frost grows across surfaces, or to prevent frost forming at all.

"Fluids go from high pressure to low pressure," Boreyko explained. "Ice serves as a humidity sink because the vapor pressure of ice is lower than the vapor pressure of water. The pressure difference causes ice to grow, but designed properly with this beetle-inspired pattern, this same effect creates a dry zone rather than frost."

This story is adapted from material from Virginia Tech, with editorial changes made by Materials Today. The views expressed in this article do not necessarily represent those of Elsevier. Link to original source.