Highly Hydrogenated Monolayer Graphene with Wide Band Gap Opening

Abstract: A thorough spectroscopic characterisation of highly hydrogenated monolayer graphene trasferred on TEM grids is herein reported. The graphene hydrogenation has the effect to distort the $sp^2$ arrangement of carbon atoms in the lattice toward a $sp^3$-like coordination, through the breaking of the $\pi$-bonds, as determined by X ray photoelectron spectroscopy of the C 1s core level. The hydrogen bonding was found to be favoured for a more distorted graphene lattice. Indeed, a 100$\%$ $sp^3$-saturation - the highest ever achieved - was observed after the hydrogenation of a sample with more pristine $sp^3$-like deformed bonds, while the flatter, more $sp^2$-arranged, sample reached a 59$\%$ $sp^3$-saturation. Electron energy loss spectroscopy confirmed the photoemission result showing the $\pi$-plasmon excitation quenching, in the totally hydrogenated sample, and significant reduction, for the other one. High loading levels of hydrogenation were also witnessed by the opening of a wide optical band gap (6.3 and 6.2 eV). The observation of the C-H stretching vibrational mode is also reported, as a direct footprint of graphene hydrogenation. Finally, valence band measurements of the 59$\%$ saturated sample suggest the coexistence of one-side and two-side hydrogenation morphologies.