Atomic-Resolution Visualization of Complex Structures in Intercalated Bilayer Graphene
ORAL
Abstract
Intercalation in two-dimensional materials has been widely investigated using spectroscopic, diffraction, and electrical measurements. However, these techniques generate spatially averaged data and provide information about the local atomic structure only inferentially. In this work, we deploy aberration-corrected scanning transmission electron microscopy to directly visualize the local atomic structure of FeCl3-intercalated bilayer (BLG) and few-layer graphene (FLG). The data exhibit a crystalline monolayer of FeCl3 inside BLG, atomically sharp intercalation boundaries, a variety of orientations for FeCl3 monolayers in FLG, and regions where the iron is reduced to form monolayer FeCl2. Our density-functional-theory calculations predict a low energy barrier of 0.04 meV/nm2 between different orientations of FeCl3, supporting the observation of multiple orientations. Furthermore, resonant-Raman spectroscopy yields evidence of two distinct graphene doping levels of EF=0.98eV and EF=1.06 in intercalated bilayer graphene, which may be attributed to the coexistence of FeCl3 and FeCl2. These results highlight the critical need for atomic-resolution studies of FeCl3 and similar intercalants to understand the dynamics of doping in multilayer graphene and graphene superlattices.
*NSF DMR
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Presenters
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Jason Bonacum
- Department of Physics and Astronomy, Vanderbilt University