A team of researchers at the Wyss Institute at Harvard University and Harvard's School of Engineering and Applied Sciences (SEAS) just moved these enticing notions much closer to reality by designing a new kind of adaptive material with tunable transparency and wettability features.
The new material was inspired by dynamic, self-restoring systems in Nature, such as the liquid film that coats your eyes. Individual tears join up to form a dynamic liquid film with an obviously significant optical function that maintains clarity, while keeping the eye moist, protecting it against dust and bacteria, and helping to transport away any wastes -- doing all of this and more in literally the blink of an eye.
The bioinspired material is a continuous liquid film that coats, and is infused in, an elastic porous substrate - which is what makes it so versatile. It is based on a core concept: any deformation of the substrate -- such as stretching, poking, or swelling - changes the size of the pores, which causes the liquid surface to change its shape.
With this design architecture in place, the team has thus far demonstrated the ability to dynamically control - with great precision - two key functions: transparency and wettability, said Xi Yao, Ph.D, Wyss Institute and SEAS postdoctoral fellow.
Sitting at rest, the material is smooth, clear and flat; droplets of water or oil on its surface flow freely off of the material. Stretching the material makes the fluid surface rougher, Yao explained. The rough surface makes it opaque for one thing, and enables one to do something never possible before: It offers the ability to make every droplet of oil or water that is placed on it reversibly start and stop in their tracks. This capability is far superior to the "switchable wettability" of other adaptive materials that exist today, Yao said, which simply switch between two states - from hydrophobic (water-hating) to hydrophilic (water-loving).
The material is a next generation of a materials platform that Aizenberg pioneered a few years ago called SLIPS. SLIPS stands for Slippery Liquid-Infused Porous Surfaces, and is a coating that repels just about anything with which it comes into contact -- from oil to water and blood.
But whereas SLIPS is a liquid-infused rigid porous surface, "the new material is a liquid-infused elastic porous surface, which is what allows for the fine control over so many adaptive responses above and beyond its ability to repel a wide range of substances. A whole range of surface properties can now be tuned, or switched on and off on demand, through stimulus-induced deformation of the elastic material," Aizenberg said.
"This sophisticated new class of adaptive materials being designed by the Institute's Adaptive Materials Technologies platform led by Joanna Aizenberg have the potential to be game-changers in everything from oil and gas pipelines, to microfluidic and optical systems, building design and construction, textiles, and more," said Wyss Founding Director Donald Ingber, M.D., Ph.D.
This story is reprinted from material from Wyss Institute, with editorial changes made by Materials Today. The views expressed in this article do not necessarily represent those of Elsevier. Link to original source.