Honeycomb Boron Allotropes with Dirac Cones: A True
Analogue to Graphene
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Abstract
We
propose a series of planar boron allotropes with honeycomb topology
and demonstrate that their band structures exhibit Dirac cones at
the K point, the same as graphene. In particular, the Dirac point
of one honeycomb boron sheet locates precisely on the Fermi level,
rendering it as a topologically equivalent material to graphene. Its
Fermi velocity (<i>v</i><sub>f</sub>) is 6.05 × 10<sup>5</sup> m/s, close to that of graphene. Although the freestanding
honeycomb B allotropes are higher in energy than α-sheet, our
calculations show that a metal substrate can greatly stabilize these
new allotropes. They are actually more stable than α-sheet sheet
on the Ag(111) surface. Furthermore, we find that the honeycomb borons
form low-energy nanoribbons that may open gaps or exhibit strong ferromagnetism
at the two edges in contrast to the antiferromagnetic coupling of
the graphene nanoribbon edges