This Graphene Doesn’t Hold Water

Physicist James Dickerson (left) is one of the first scientists to probe graphene’s interaction with water. Pictured with him is graduate student Saad Hasan.

Physicist James Dickerson (left) is one of the first scientists to probe graphene’s interaction with water. Pictured with him is graduate student Saad Hasan.

Windshields that shed water so effectively they don’t need wipers. Ship hulls so slippery that they glide through water more efficiently than ordinary hulls. These are some potential applications for graphene, one of the hottest new materials in the field of nanotechnology, raised by the research of James Dickerson, assistant professor of physics.

Dickerson and colleagues have figured out how to create a freestanding film of graphene oxide and alter its surface roughness so that it either causes water to bead up and run off or spread out in a thin layer.

“Graphene films are transparent and, because they are made of carbon, they are very inexpensive to make,” Dickerson says. “The technique we use can be rapidly scaled up to produce it in commercial quantities.” His approach is documented in an article published online by the journal ACSNano on Nov. 26, 2010.

Graphene is made up of sheets of carbon atoms arranged in rings—something like molecular chicken wire. One of the thinnest materials possible, it is 10 times stronger than steel and conducts electricity better at room temperature than any other known material. Graphene’s exotic properties have attracted widespread scientific interest, but Dickerson is one of the first to investigate how it interacts with water.

Many scientists make graphene by using a dry method called “mechanical cleavage” that involves rubbing or scraping graphite against a hard surface. The technique produces sheets that are both extremely thin and extremely fragile. Dickerson’s method can produce sheets equally thin but considerably stronger, and is already used commercially to produce a variety of coatings and ceramics. Known as electrophoretic deposition, this “wet” technique combines an electric field within a liquid medium to create nanoparticle films that can be transferred to another surface.

Dickerson and colleagues found they could change the manner in which graphene oxide particles assemble into a film by varying the pH of the liquid medium and the electric voltage used in the process. One pair of settings lays down the particles in a “rug” arrangement that creates a nearly atomically smooth surface. A different pair of settings causes particles to clump into tiny “bricks” forming a bumpy and uneven surface. The rug surface causes water to spread out in a thin layer, while the brick surface causes water to bead up and run off.

Dickerson is pursuing an approach that could create film that enhances these water-associated properties, making them even more effective at either spreading out water or causing it to bead up and run off. The development of coatings with these enhanced properties, called super-hydrophobic and super-hydrophilic, has created significant academic and commercial interest. Potential applications range from self-cleaning glasses and clothes to antifogging surfaces to corrosion protection and snow-load protection on buildings. But effective, low-cost and durable coatings have yet to make it out of the laboratory.

Dickerson’s idea is to apply his basic procedure to “fluorographene”—a fluorinated version of graphene that is a two-dimensional version of Teflon—recently produced by Kostya S. Novoselov and Andre K. Geim at the University of Manchester, who received the 2010 Nobel Prize for the discovery of graphene. Normal fluorographene under tension should be considerably more effective in repelling water than graphene oxide. Therefore, there’s a good chance a “brick” version and a “rug” version would have extreme water-associated effects, Dickerson figures.

Graduate students Saad Hasan, John Rigueur, Robert Harl and Alex Krejci, postdoctoral research scientist Isabel Gonzalo de Juan, and Associate Professor of Chemical and Biomolecular Engineering Bridget R. Rogers contributed to the research, which was funded by a Vanderbilt Discovery grant and by the National Science Foundation.

Share this post