Experimental Realization of Two-Dimensional Boron Sheets

TL;DR

This paper reports the first experimental creation of two-dimensional boron sheets, revealing their structure, stability, and potential for electronic applications, marking a significant advancement in boron nanomaterials.

Contribution

It provides the first experimental demonstration of stable 2D boron sheets with specific lattice structures, expanding the understanding of boron nanostructures.

Findings

Two types of boron sheet structures identified

Boron sheets are relatively stable against oxidation

Weak interaction with substrate suggests potential for electronic applications

Abstract

Boron is the fifth element in the periodic table and possesses rich chemistry second only to carbon. A striking feature of boron is that B12 icosahedral cages occur as the building blocks in bulk boron and many boron compounds. This is in contrast to its neighboring element, carbon, which prefers 2D layered structure (graphite) in its bulk form. On the other hand, boron clusters of medium size have been predicted to be planar or quasi-planar, such as B12+ , B13+, B19-, B36, and so on. This is also in contrast to carbon clusters which exhibit various cage structures (fullerenes). Therefore, boron and carbon can be viewed as a set of complementary chemical systems in their bulk and cluster structures. Now, with the boom of graphene, an intriguing question is that whether boron can also form a monoatomic-layer 2D sheet structure? Here, we report the first successful experimental realization of 2D boron sheets. We have revealed two types of boron sheet structures, corresponding to a triangular boron lattice with different arrangements of the hexagonal holes. Moreover, our boron sheets were found to be relatively stable against oxidization, and interacts only weekly with the substrate. The realization of such a long expected 2D boron sheet could open a door toward boron electronics, in analogous to the carbon electronics based on graphene.