Using density functional theory based calculations mainly, we investigated the interaction between [Rh^III(OEP)(Cl)] (OEP = octaethylporphyrin) and a graphite basal surface, and the electronic structure of [Rh^III(OEP)(Cl)]/graphite. Because the [Rh^III(OEP)(Cl)] complex does not have a singlet occupied molecular orbital on the porphyrin ring, the π-π stacking interaction between porphyrin and graphite is not present and their interaction is dominated by dispersion forces. The lowest unoccupied molecular orbital (band) of [Rh^III(OEP)(Cl)]/graphite is a σ bonding orbital between Rh^III and graphite that will cause fast electron transfer from [Rh^III(OEP)(Cl)] to graphite during the CO electro-oxidation; this would be a reason why the carbon-supported [Rh^III(OEP)(Cl)] has high catalytic activity for CO electro-oxidation.