We have measured spatial Raman maps of hydrogen intercalated quasi-free standing monolayer graphene (QFSMLG) on SiC(0001). We compare Raman spectra of QFSMLG with spectra of bare buffer layer, single-layer graphene, and bare SiC substrate.We also present the evolution of QFSMLG Raman spectra with the temperature and duration of hydrogen intercalation.
We present new Raman modes, and, on the basis of polarization resolved measurements, we attribute them to the totally symmetric out-of-plane optical phonon (ZO) modes of the buffer layer at the Γ and M points. We show that these modes are eliminated by hydrogen intercalation; thus, they indicate onset of buffer layer decoupling from the SiC substrate.
The spatial mapping of Raman scattering reveals details of the optimal hydrogen intercalation at elevated temperatures. Further increase of the intercalation temperature leads to etching of the buffer layer and underlying SiC substrate.
Therefore, we show that interplay between temperature and intercalation time is a promising route towards increased graphene grain size with reduced lattice strain.