Aqueous oxalic acid forms surface Cr-III-oxalato complexes with suspended chromium(III) oxide particles; the FTIR spectra demonstrate that both carboxylate groups of the ligand are bound to surface Cr-III. Surface complexation is followed by changes in the surface redox potential toward more negative values and by the dissolution of the oxide. The dissolving steady state potential is in the range -60 to -210 mV against SHE. During surface conditioning, traces of oxidants at the interface are reduced, and some reduced metal ions accumulate. Minor amounts of dissolved Cr-II are generated and can be collected at a vicinal ring electrode set at -60 mV. In agreement, dissolution kinetics suggest that generation of Cr-II by ligand-to-metal charge transfer within the surface complexes produces a large increase in the rate of phase transfer, as expected from the properties of Cr-III and Cr-II. Added chromous salts also catalyze the dissolution through intervalence charge transfer within an oxalato-bridged Cr-III-L-Cr-II surface dimeric complex. The rate of dissolution at 65 degrees C follows a Langmuir-Hinshelwood dependence on oxalic acid concentration, a power law (order 0.31) dependence on proton concentration, and an a + b[Cr-II](0.64) dependence on [Cr(II)]. The Langmuir-Hinshelwood parameters are interpreted in terms of the stability constant of the surface Cr-III-oxalato complex.