Anomalous magnetism in hydrogenated graphene

Abstract

We revisit the problem of local moment formation in graphene due to chemisorption of individual atomic hydrogen or other analogous sp3 covalent functionalizations. We describe graphene with the single orbital Hubbard model, so that the H chemisorption is equivalent to a vacancy in the honeycomb lattice. In order to circumvent artefacts related to periodic unit cells, we use either huge simulation cells of up to 8×105 sites, or an embedding scheme that allows the modelling of a single vacancy in an otherwise pristine infinite honeycomb lattice. We find three results that stress the anomalous nature of the magnetic moment (m) in this system. First, in the non-interacting (U=0), zero temperature (T=0) case, the m(B) is a continuous smooth curve with divergent susceptibility, different from the step-wise constant function found for a single unpaired spins in a gapped system. Second, for U=0 and T>0, the linear susceptibility follows a power law T-α with an exponent of α=0.77 different from conventional Curie's law. For U>0, in the mean field approximation, the integrated moment is smaller than m=1μB, in contrast with results using periodic unit cells. These three results highlight that the magnetic response of the local moment induced by sp3 functionalizations in graphene is different both from that of local moments in gaped systems, for which the magnetic moment is quantized and follows a Curie law, and from Pauli paramagnetism in conductors, for which a linear susceptibility can be defined at T=0.