Paper No. 14
Presentation Time: 5:10 PM
EVALUATING THE ROLE OF GROUNDWATER IN THE GLOBAL OCEANIC NEODYMIUM BUDGET
Distinct εNd(0) values of the Atlantic, Indian, and Pacific Oceans necessitate that the oceanic residence time of Nd, τNd be on the order of, or less than, the ocean mixing time of ~ 500 - 1500 years. Nonetheless, estimates of τNd, based on river influxes, range from 4000 to 15,000 years. To reconcile the oceanic Nd budget and lower the residence time by roughly a factor of 10, an additional, missing Nd flux (i.e., 5.4 x 107 moles of Nd/year) has been proposed [K. Tachikawa, V. Athias, C. Jeandel, J. Geophys. Res 108 (2003) 3253 doi:10.1029/1999JC000285]. We demonstrate that submarine groundwater discharge (SGD) can account for this missing Nd flux. Neodymium concentrations (n = 730) and εNd(0) values (n = 58) for groundwaters, obtained from the literature, were used along with recent estimates of SGD (6% of river discharge on a global basis) to examine if SGD to the coastal oceans could account for the missing flux. Employing mean Nd concentrations from the compiled data base (i.e., 31.8 nmol/kg for all 730 analyses and 11.3 nmol/kg for 141 groundwater samples from a coastal aquifer), the global SGD flux of Nd is estimated to range between 2.9 x 107 and 8.1 x 107 moles/year. These estimates are of the same order of magnitude, and within a factor of 2, of the missing Nd flux. Applying the SGD Nd flux estimates, the global average εNd(0) of SGD is calculated to be -9.1, which is similar to our estimate for the missing Nd flux (-9.2), and in agreement with the mean (± SD)εNd(0) measured in groundwaters (i.e., εNd(0) = -8.9 ± 4.2). The similarities in the estimated SGD Nd flux and corresponding εNd(0) values to the magnitude and isotope composition of the missing Nd flux are compelling, and suggest that discharge of groundwater to the oceans can account for the missing Nd flux. Our SGD flux estimates for Nd suggest an average oceanic Nd residence time of 600 years.