Grain Boundaries in Graphene on SiC(000(1)over-bar) Substrate

Grain boundaries in epitaxial graphene on the SiC(000 (1) over bar) substrate are studied using scanning tunneling microscopy and spectroscopy. All investigated small-angle grain boundaries show pronounced out-of-plane buckling induced by the strain fields of constituent dislocations. The ensemble of observations determines the critical misorientation angle of buckling transition theta(c) = 19 +/- 2 degrees. Periodic structures are found among the flat large-angle grain boundaries. In particular, the observed theta = 33 +/- 2 degrees highly ordered grain boundary is assigned to the previously proposed lowest formation energy structural motif composed of a continuous chain of edge-sharing alternating pentagons and heptagons. This periodic grain boundary defect is predicted to exhibit strong valley filtering of charge carriers thus promising the practical realization of all-electric valleytronic devices.

Grain Boundaries in Graphene on SiC(000(1)over-bar) Substrate

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Nanolithography of the nanocorral structure of chemisorbed oxygen atoms on the graphitic lattice

Controlling crystal cleavage in focused ion beam shaped specimens for surface spectroscopy

Scanning Tunneling Microscopy for Molecules: Effects of Electron Propagation into Vacuum

Nanolithography of the nanocorral structure of chemisorbed oxygen atoms on the graphitic lattice

Controlling crystal cleavage in focused ion beam shaped specimens for surface spectroscopy

Scanning Tunneling Microscopy for Molecules: Effects of Electron Propagation into Vacuum