Researchers from Brown University have found a way to flip the horizontal channels between graphene sheets to make them vertical, which is an ideal orientation for filtration. Image: Hurt lab/Brown University.When sheets of two-dimensional (2D) nanomaterials like graphene are stacked on top of each other, tiny gaps form between the sheets that have a wide variety of potential uses. In a paper in Nature Communications, a team of researchers from Brown University reports finding a way to orient those gaps, called nanochannels, in a way that makes them more useful for filtering nanoscale contaminants from water and other liquids.
"In the last decade, a whole field has sprung up to study these spaces that form between 2D nanomaterials," said Robert Hurt, a professor in Brown's School of Engineering and co-author of the paper. "You can grow things in there, you can store things in there, and there's this emerging field of nanofluidics where you're using those channels to filter out some molecules while letting others go through."
There's a problem, however, with using these nanochannels for filtration, and it has to do with the way those channels are oriented. Like a notebook made from stacked sheets of paper, graphene stacks are thin in the vertical direction compared to their horizontal length and width, which means that the channels between the sheets are likewise oriented horizontally. That's not ideal for filtration, because liquid has to travel a relatively long way to get from one end of a channel to the other.
It would be better if the channels were perpendicular to the orientation of the sheets. In that case, liquid would only need to traverse the relatively thin vertical height of the stack rather than the much longer length and width. But until now, no one had come up with a good way to make vertically oriented graphene nanochannels. That is until Muchun Liu, a former postdoctoral researcher in Hurt's lab, figured out a novel way to do it.
Liu's method involves stacking graphene sheets on an elastic substrate, which is placed under tension to stretch it out. After the sheets are deposited, the tension on the substrate is released, which allows it to contract. When that happens, the graphene assemblage on top wrinkles into sharp peaks and valleys.
"When you start wrinkling the graphene, you're tilting the sheets and the channels out of plane," said Liu, who is now a researcher at Massachusetts Institute of Technology. "If you wrinkle it a lot, the channels end up being aligned almost vertically."
Once the channels are nearly vertical, the assemblage is encased in epoxy, and the tops and bottoms are then trimmed away, which opens the channels all the way through the material. The researchers have dubbed these assemblages VAGMEs (vertically aligned graphene membranes).
"What we end up with is a membrane with these short and very narrow channels through which only very small molecules can pass," Hurt said. "So, for example, water can pass through, but organic contaminants or some metal ions would be too large to go through. So you could filter those out."
Proof-of-concept testing demonstrated that water vapor could pass easily through a VAGME, while hexane – a larger organic molecule – was filtered out. The researchers plan to continue developing the technology, with an eye toward potential industrial or household filtering applications.
This story is adapted from material from Brown University, with editorial changes made by Materials Today. The views expressed in this article do not necessarily represent those of Elsevier. Link to original source.