▎ 摘　　要

Hydrogen, generated from water splitting, is postulated as one of the most promising alternatives to fossil fuels. In this context, direct hydrogen generation by electrolysis and fixation to graphene oxide in an aqueous sus-pension could overcome storage and distribution problems of gaseous hydrogen. This study presents time -resolved determination of the electrochemical hydrogenation of GO by in-situ Raman spectroscopy, simulta-neous to original functional groups elimination.Hydrogenation is found favoured by dynamic modulation of the electrochemical environment compared to fixed applied potentials, with a 160% increase of C-H bond formation. Epoxide groups suppression and gener-ated hydroxide groups point at these epoxide groups being one of the key sites where hydrogenation was possible. FTIR revealed characteristic symmetric and asymmetric stretching vibrations of C-H bonds in CH2 and CH3 groups. This shows that hydrogenation is significantly also occurring in defective sites and edges of the graphene basal plane, rather than H-Csp(3) groups as graphane. We also determined a -0.05 VRHE reduction starting potential in alkaline electrolytes and a 150 mV cathodic delay in acid electrolytes. The identified key parameters role, together with observed diverse C-H-x groups formation, points at future research directions for large-scale hydrogen storage in graphene.