UNIVERSITY PARK, Pa. — Demonstrating that a material thought to be always chemically inert, hexagonal boron nitride (hBN), can be turned chemically active holds potential for a new class of catalysts with a wide range of applications, according to an international team of researchers.
hBN is a layered material and monolayers can be exfoliated like in graphene, another two-dimensional material. However, there is a key difference between the two.
“While hBN shares similar structure as graphene, the strong polar bonds between the boron and nitride atoms makes hBN unlike graphene in that it is chemically inert and thermally stable at high temperature,” said Yu Lei, postdoctoral scholar in physics at Penn State and first co-author in the study published in Materials Today.
If hBN was chemically active and not inert, that would enable more uses for it, including being a useful, cost-efficient catalyst support similar to graphene. This would be useful for practical applications like in a gasoline-powered automobile or to convert carbon for helping reduce greenhouse gases to other products.
“The catalytic converter in your gasoline car has the precious metal platinum in it to process the conversion of harmful gases into less harmful gases,” said Jose Mendoza-Cortes, assistant professor of chemical engineering and materials science at Michigan State University. “However, this is expensive because you need to put in a lot of platinum atoms for the catalysis. Now imagine that you only need to put one or two, and still get the same performance.”
Platinum is also used as a catalyst for many other types of practical chemical reactions, and the platinum atoms that perform the conversion are usually on the surface, while the ones below are just there as structural support.