- Fundamental information concerning the mechanism of electron transfer from reduced heteropolytungstates (POMred) to O2, and the effect of donor-ion charge on reduction of O2 to superoxide anion (O2•-), is obtained using an isostructural series of 1e--reduced donors: α-Xn+W12O40(9-n)-, Xn+ = Al3+, Si4+, P5+. For all three, a single rate expression is observed: −d[POMred]/dt = 2k12[POMred][O2], where k12 is for the rate-limiting electron transfer from POMred to O2. At pH 2 (175 mM ionic strength), k12 increases from 1.4 ± 0.2 to 8.5 ± 1 to 24 ± 2 M-1s-1 as Xn+ is varied from P5+ (3red) to Si4+ (2red) to Al3+ (1red). Variable-pH data (for 1red) and solvent-kinetic isotope (KIE = kH/kD) data (all three ions) indicate that protonated superoxide (HO2·) is formed in two stepselectron transfer, followed by proton transfer (ET−PT mechanism)rather than via simultaneous proton-coupled electron transfer (PCET). Support for an outersphere mechanism is provided by agreement between experimental k12 values and those calculated using the Marcus cross relation. Further evidence is provided by the small variation in k12 observed when Xn+ is changed from P5+ to Si4+ to Al3+, and the driving force for formation of O2•- (aq), which increases as cluster-anion charge becomes more negative, increases by nearly +0.4 V (a decrease of >9 kcal mol-1 in ΔG°). The weak dependence of k12 on POM reduction potentials reflects the outersphere ET−PT mechanism: as the anions become more negatively charged, the “successor-complex” ion pairs are subject to larger anion−anion repulsions, in the order [(3ox3-)(O2•-)]4- < [(2ox4-)(O2•-)]5- < [(1ox5-)(O2•-)]6-. This reveals an inherent limitation to the use of heteropolytungstate charge and reduction potential to control rates of electron transfer to O2 under turnover conditions in catalysis.