Though they’re touted as ideal for electronics, two-dimensional materials like graphene may be too flat and hard to stretch to serve in flexible, wearable devices. “Wavy” borophene might be better, according to Rice University scientists.

The Rice lab of theoretical physicist Boris Yakobson and experimental collaborators observed examples of naturally undulating, metallic borophene, an atom-thick layer of boron, and suggested that transferring it onto an elastic surface would preserve the material’s stretchability along with its useful electronic properties.

Highly conductive graphene has promise for flexible electronics, Yakobson says, but it is too stiff for devices that also need to stretch, compress or even twist. But borophene deposited on a silver substrate develops nanoscale corrugations. Weakly bound to the silver, it could be moved to a flexible surface for use.

The research appears this month in the American Chemical Society journal Nano Letters.

Rice collaborated with experimentalists at Argonne National Laboratory and Northwestern University to study borophene, which has been made in small quantities. Under the microscope, borophene displays corrugations that demonstrate its wavy nature, meaning it can be highly stretched once removed from the substrate, or reattached to a soft one, Yakobson says.

The Rice group builds computer simulations to analyze the properties of materials from the atoms up. Simulations by first author Zhuhua Zhang, a postdoctoral researcher in Yakobson’s group, showed that hexagonal vacancies in borophene help soften the material to facilitate its corrugated form.

“Borophene is metallic in its typical state, with strong electron-phonon coupling to support possible superconductivity, and a rich band structure that contains Dirac cones, as in graphene,” Yakobson says.

There is a hitch: Borophene needs the underlying structure to make it wavy. When grown on a featureless surface, its natural form resembles graphene, the flat, chicken-wire arrays of carbon atoms. Zhang says borophene is better seen as a triangular lattice with periodic arrays of hexagonal vacancies.

Borophene prefers to be flat because that’s where its energy is lowest, Yakobson says. But surprisingly, when grown on silver, borophene adopts its accordion-like form while silver reconstructs itself to match. The corrugation can be retained by “re-gluing” boron onto another substrate.

“This wavy conformation so far seems unique due to the exceptional structural flexibility and particular interactions of borophene with silver, and may be initially triggered by a slight compression in the layer when a bit too many boron atoms get onto the surface,” Zhang says.

Co-authors of the paper are Rice alumnus Zhili Hu, Andrew Jacob Mannix, and Brian Kiraly of Argonne National Laboratory and Northwestern; Nathan Guisinger of Argonne National Laboratory; and Mark Hersam of Northwestern.

The Department of Energy, the Office of Naval Research, and the National Science Foundation (NSF) supported the research. The researchers utilized the XSEDE and NSF-supported DAVinCI supercomputer, both administered by Rice’s Center for Research Computing and procured in a partnership with Rice’s Ken Kennedy Institute for Information Technology.

Source: Rice University