Triple oxygen isotope systematics of CO2 hydroxylation

Kinetic isotope effects occurring during carbonate precipitation impact the accuracy of paleoclimate records. One rate-limiting process is CO2 absorption, which, at high pH, primarily proceeds through hydroxylation, where aqueous CO2 and OH− react to form HCO3−. In this study, we investigated the triple oxygen isotope fractionation (18O/16O and 17O/16O) associated with the hydroxylation reaction. We experimentally determined the extent of the kinetic isotope effects superimposed on the reacting CO2 and OH− during hydroxylation, using high-pH precipitation reactions. These results were compared to the equilibrium triple oxygen isotope fractionation between H2O and OH− modeled using quantum chemical computations.Our quantum chemical modeling confirms the previously suggested equilibrium θeqH2O/OH- of 0.5296 at 25 °C. Our empirical data show a kinetic isotope effect superimposed on the OH− involved in the hydroxylation reaction of approximately −16.4‰ for the fractionation of 18O/16O and a corresponding slope of 0.514 in triple oxygen isotope space. The θeffectiveH2O/OH- for the fractionation between water and the reacting OH− is 0.523.In order to identify and potentially correct kinetic isotope effects in carbonates, it is important to understand the fractionations occurring during precipitation. Our results enable a more accurate modeling of kinetic isotope effects in triple oxygen isotope space, particularly the slope of hydroxylation. The θhydroxylation is dependent on the isotope composition of the ambient water, CO2, and the temperature. We estimate that θhydroxylation is approximately 0.532 for carbonates growing in 25 °C seawater. In alkaline lakes, it is approximately 0.539.