Plastic Films Pin Water Droplets Like Rose Petals Do

Materials scientists often turn to the plant kingdom for ideas on how to design surfaces that trap or repel water. Some have mimicked the surfaces of rose petals to engineer nanoscale patterns that cling to water droplets. Now researchers report a simple method to print large-area, water-pinning plastic films (Langmuir 2014, DOI:10.1021/la4034996). With a practical manufacturing method, these water-trapping films could find commercial applications, such as controlling condensation in greenhouses or liquid flow in microfluidic devices.

In the early morning, dew clings to rose petals; when the sun rises, the dewdrops act like tiny lenses, making diffraction patterns that attract pollinating insects, says Jaslyn Bee Khuan Law, a materials scientist at the Agency for Science, Technology, and Research (A*STAR), in Singapore. A drop of water will cling to a rose petal even when it’s tilted or held upside down. The petals can hold onto these droplets because their surfaces consist of closely packed conical structures a few micrometers across. These microscale surface patterns tweak the surface tension of the water droplets, causing them to cling to the petals.

Researchers first mimicked this effect by using rose petals as templates to mold water-pinning structures onto polyvinyl acetate and polydimethylsiloxane films. Others have made water-pinning surfaces by using complex methods, such as chemical vapor deposition, to carve out similarly shaped, nanoscale structures in silicon or metals. Making the features on the nanoscale enhanced the water-pinning effect.