Data_Sheet_1_The Effect of Particle Composition and Concentration on the Partitioning Coefficient for Mercury in Three Ocean Basins.docx

The downward flux of sinking particles is a prominent Hg removal and redistribution process in the ocean; however, it is not well-constrained. Using data from three U.S. GEOTRACES cruises including the Pacific, Atlantic, and Arctic Oceans, we examined the mercury partitioning coefficient, K_d, in the water column. The data suggest that the K_d varies widely over three ocean basins. We also investigated the effect of particle concentration and composition on K_d by comparing the concentration of small-sized (1–51 μm) suspended particulate mass (SPM) as well as its compositional fractions in six different phases to the partitioning coefficient. We observed an inverse relationship between K_d and suspended particulate mass, as has been observed for other metals and known as the “particle concentration effect,” that explains much of the variation in K_d. Particulate organic matter (POM) and calcium carbonate (CaCO₃) dominated the Hg partitioning in all three ocean basins while Fe and Mn could make a difference in some places where their concentrations are elevated, such as in hydrothermal plumes. Finally, our estimated Hg residence time has a strong negative correlation with average log bulk K_d, indicating that K_d has significant effect on Hg residence time.