We present in situ electrode measurements of sediment resistivity, pore water oxygen, and pore waterpH from three stations between 2300 and 3000 m depth on the Ontong‐Java Plateau in the western equatorial Pacific. One of these stations is also the site of a concurrent benthic chamber incubation experiment Jahnkeet al., 1994. The pore water oxygen data and a steady state diffusion and reaction model constrain the depth‐dependent rate of oxic respiration in the sediments and imply a diffusive flux of oxygen to the sediments of 10–21 μmol cm−2yr−1. Given these respiration rates, the pore waterpH data cannot be explained without calcite dissolution driven by metabolically produced CO2. The dissolution necessary to explain the observations, quantified by a statistical approach, is 3.5–6 μmol cm−2yr−1, which corresponds to at least 20–40 of the calcite rain to these sediments. Over 65 of the total dissolution is driven by metabolic CO2. Oxygen fluxes and net calcite dissolution constrained by the electrode data are compatible with the benthic chamber measurements ofJahnke et al.1994. The dissolution flux, while a significant part of the early diagenesis of calcite in these sediments, is less than would be predicted by earlier models of dissolution, andJahnke et al.1994 probably could not distinguish it from zero with the benthic chamber technique. The dissolution rates found in this study are lower than previous estimates because the respiration reaction is concentrated near the sediment‐water interface, and the calcite dissolution rate constants are very small. The statistical evaluation of the pore waterpH data and model constrain the calcite dissolution rate constant to 0.005–0.16 d−1, following the general trend of lower values determined by in situ techniques rather t
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