Abstract
Calcium carbonate (CaCO3) dissolution plays a key role in the marine carbon and alkalinity cycles and the regulation of atmospheric CO2 levels across geological time scales. Until now, most attention has focused on dissolution in the deep sea, while dissolution in coastal and shelf environments remains poorly constrained. Here, we present a synthesis of CaCO3 dissolution rates in sediments of coastal and shelf environments and integrate them into an updated global marine CaCO3 budget. The highest areal dissolution rates occur in coral reefs and lagoons, and in seagrass-dominated banks and bays, as these sediments combine high amounts of soluble high-magnesium calcite with deep oxygen penetration and high organic matter input that facilitate dissolution. Nevertheless, carbonate-poor shelves contribute as much (similar to 45%) as coral reefs and lagoons to global coastal and shelf carbonate dissolution. Total coastal and shelf dissolution is estimated at 11 +/- 9 Tmol yr(-1) and thus provides similar to 8% of the total CaCO3 dissolution in the ocean. Combining these dissolution rates with published estimates of production, terrestrial input, and burial, mass balance closure requires an off-shelf lateral export of similar to 15 Tmol CaCO3 yr(-1). Although this estimate carries large uncertainty (>100%), it suggests that a significant fraction of the CaCO3 produced on the shelf is transferred from a short-term climate buffer in the shelf seafloor to a long-term climate buffer in the deep-sea seafloor.