Long-range interactions of bismuth growth on monolayer epitaxial graphene at room temperature
![Fig. 1 – (a) Atomically resolved STM image (7 nm · 7 nm) of MEG on 4H-SiC (0001) and the corresponding Fast Fourier transform (inset). White solid arrow points to a 1 · 1-G spot and green dashed arrow to a 6 · 6-SiC spot [36,43]. Imaging conditions: Vs = 40 mV, I = 0.15 nA. (b) The dI/dV–V curve obtained on clean surface of MEG. (A colour version of this figure can be viewed online.)](https://static.wixstatic.com/media/c8210a_bc4d256ecb124b9a9a2c3b7735e5242f~mv2.jpg/v1/fill/w_140,h_71,al_c,q_80,usm_0.66_1.00_0.01,blur_2,enc_auto/c8210a_bc4d256ecb124b9a9a2c3b7735e5242f~mv2.jpg)
Long-range electronic interaction between Bismuth (Bi) adatoms on graphene formed on a 4H-SiC (0 0 0 1) substrate are clearly observed at room temperature (T = 300 K). Using scanning tunneling microscopy (STM) and density functional theory (DFT) calculations, we have demonstrated that such oscillatory interaction results mainly from the mediation of graphene Dirac-like electrons and the effect of the corrugated surface of SiC substrate. These two factors cause the observed oscillatory interaction with characteristic distribution distances and linear arrangements of Bi adatoms. The present study sheds light on understanding and controlling the nucleation of adatoms and subsequent growth of nanostructures on graphene surface.
