Dissolved silica in the subterranean estuary and the impact of submarine groundwater discharge on the global marine silica budget

Abstract

Groundwater's role in the global marine budget of dissolved silica (DSi), an essential nutrient, is constrained using DSi groundwater concentrations from multiple endmember lithologies and a global terrestrial submarine groundwater discharge (SGD) model. We report new DSi concentrations in nine subterranean estuaries throughout the world, including Panama, Mauritius, Guam, Yucatan (Mexico), Chile, Argentina, Southwest Florida (USA), Long Island Sound (USA) and Waquoit Bay (USA). These new data are augmented with a literature survey of DSi endmember concentrations in the subterranean estuary to determine the global DSi endmember in SGD, classified by the regional lithology (carbonate, shale, sandstone, extrusive igneous, shield and “complex”). DSi fluxes to the ocean from terrestrial (fresh) SGD equal 0.7 ± 0.1 Tmol y−1, more than half of which enters the Pacific Ocean. Non-conservative DSi enrichment was observed in marine groundwaters circulated through extrusive igneous and complex lithology sediments for twenty different study sites. Dissolution rate calculations indicate that non-conservative DSi enrichments in marine groundwaters can be supported, in part, by lithogenic dissolution of the coastal sediment, rather than biogenic silica dissolution. We make preliminary estimates of DSi inputs via marine SGD in shallow coastal aquifers of ~3 Tmol y−1. Considering recent revisions to the marine silica budget (e.g., increased estimates of biogenic silica storage via reverse weathering reactions, increased estimates of standing stocks of biogenic silica, and changing estimates of silica burial efficiency), sources and sinks in the marine Si budget can be balanced when taking into account estimates of new DSi inputs from total SGD (terrestrial and marine flow paths). These findings impact the residence time of oceanic Si and mass balances of the stable Si isotopes, as well as associated silicate weathering products, including Li and Ge.