News Release

Making graphene-based desalination membranes less prone to defects, better at separating

Peer-Reviewed Publication

American Association for the Advancement of Science (AAAS)

By embedding supporting carbon nanotube networks, researchers have developed a way to improve the performance of thin graphene-based membranes designed for water desalination, making it less likely they crack or tear and thus undermine the entire desalination system. According to tests of the material, the new graphene hybrid membrane shows high water permeance and salt separation performance at previously unattainable scales. "The study brings the membrane area from micrometer-scale to centimeter-scale, which is large enough to be tested in a bench-scale membrane system, representing a major milestone in scaling up nanoporous graphene membranes," writes Baoxia Mi in a related Perspective. An ideal material for removing salt from seawater to create potable freshwater should be thin, strong enough to withstand extended use and contain uniformly sized and distributed pores for efficient ion separation. Nanoporous 2D graphene membranes are well suited for this purpose and have experimentally demonstrated exceptionally fast and efficient desalination. However, as the surface area of these membranes increases, they become more prone to defects and damage, which significantly reduces their ability to separate unwanted substances from water. Because of this, the use of ultrathin graphene nanomesh materials has been limited to proof-of-concept demonstrations using micrometer-scale flakes. Here, Yanbing Yang and colleagues present a method for fabricating graphene membranes that overcome these limitations. Yang et al. developed an atomically thin graphene nanomesh (GNM) reinforced by an interwoven network of single-walled carbon nanotubes (SWNT). The SWNTs physically partition the GNM material to form a structural framework - not unlike the Voronoi-like cells of a dragonfly wing - which provides mechanical stability at centimeter scales. Furthermore, the network of SWNT blocks the spread of cracks or tears in the graphene, effectively constraining any damage to a small area. Further testing of the material shows its highly efficient desalination capabilities. According to Yang et al., because there are no fundamental limitations in producing large sheets of the SWNT-reinforced graphene, membranes could possibly be readily scaled up to meter scales. In the related Perspective, Mi notes that despite the "intriguing work" by this team, the technology still has a way to go before it can be implemented in real-world desalination systems.

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