A team of scientists led by the Department of Energy’s Oak Ridge National Laboratory has developed a novel way to produce two-dimensional nanosheets by separating bulk materials with nontoxic liquid nitrogen. The environmentally friendly process generates a 20-fold increase in surface area per sheet, which could expand the nanomaterials’ commercial applications.
Nanosheets of boron nitride could be used in separation and catalysis, such as transforming carbon monoxide to carbon dioxide in gasoline-powered engines. They also may act as an absorbent to mop up hazardous waste. Zhu said the team’s controlled gas exfoliation process could be used to synthesize other 2D nanomaterials such as graphene, which has potential applications in semiconductors, photovoltaics, electrodes and water purification.
Because of the versatility and commercial potential of one-atom-thick 2D nanomaterials, scientists are seeking more efficient ways to produce larger sheets. Current exfoliation procedures use harsh chemicals that produce hazardous byproducts and reduce the amount of surface area per nanosheet, Zhu said.
“In this particular case, the surface area of the boron nitride nanosheets is 278 square meters per gram, and the commercially available boron nitride material has a surface area of only 10 square meters per gram,” Zhu said. “With 20 times more surface area, boron nitride can be used as a great support for catalysis.”
Further research is planned to expand the surface area of boron nitride nanosheets and also test their feasibility in cleaning up engine exhaust and improving the efficiency of hydrogen fuel cells.
Along with Zhu, several co-authors participated in the paper, “Controlled Gas Exfoliation of Boron Nitride into Few-Layered Nanosheets,” including ORNL’s Sheng Dai, Xiang Gao, Qian Li, Shannon M. Mahurin and Wenshuai Zhu; Yanhong Chao, Hongping Li and Huaming Li with Jiangsu University and Meijun Li from the University of Tennessee. The Angewandte Chemiestudy can be found here.
The study was supported by the DOE Office of Science. Additional funding was provided by the Liane Russell Distinguished Early Career Fellowship through the Laboratory Directed Research and Development program. Zhu joined ORNL in 2014 as one of the lab’s first Russell Fellows, and her primary area of research is on synthetic control of hybrid nanomaterials for catalytic applications.