Graphene π-bands on Si-terminated Vicinal SiC(0001)
S. Tanaka and F. Komori
Massless π bands of graphene grown on a SiC(0001) substrate can be modified by the scattering at the boundaries and the interface superstructure. We investigated the π band structure and width of the single- and double-layer grown on a Si-terminated vicinal SiC(0001) substrate using angle-resolved photoemission spectroscopy (ARPES). The π electron scattering at the substrate steps makes the spectrum width anisotropic, but no difference in the π band shape. Quasi-2×2 replicas of the π band due to the interface 6√3×6√3-R30° superstructure were observed in the single-layer graphene while they were absent in the double-layer graphene.
Single- and double-layer graphenes were grown on Si-terminated surface of nitrogen-doped 6H-SiC(0001) substrates vicinal to the [11-20] (4° off) direction. [1] The substrate surface was first etched in H2 gas, and a SiON thin film [2] was successively formed on the surface by annealing in N2 gas. Finally, graphene layer was made on this substrate by annealing in N2 gas over 1900 K for up to a few hundred sec. The average thickness of the graphene can be controlled by the annealing temperature and time. The STM images of the graphene are shown in Fig. 1. The graphene covers all the substrate including the step-edge areas.
Figure 2 shows the results of ARPES.[3] The π band spectrum in the direction perpendicular to the step-down direction (K1) has a narrower width in the momentum distribution than the band in the other direction (K2) when the binding energy from Fermi energy EF is smaller than 0.2 eV. However, there is no significant difference in the π band shape between them. The anisotropy of the line width is attributed to the π electron scattering at the curved areas on the substrate step edges. The origin of the observed nonlinear dispersion of the π band is not due to the electron scatterings at defects of the graphene, but to the many-body effects and/or the electronic potential due to the interface 6√3×6√3-R30° structure of carbon atoms, which cause the quasi-2×2 replica π bands in ARPES.
References
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- K. Nakatsuji, et. al., Phys. Rev. B 82, 045428 (2010).