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Understanding decadal changes in the coastal carbonate system is essential for predicting how the health of these waters responds to anthropogenic drivers, such as changing atmospheric conditions and riverine inputs. However, studies that quantify the relative impacts of these drivers are lacking. In this study, the primary drivers of decadal trends in the surface carbonate system, and the spatiotemporal variability in these trends, are identified for a large coastal plain estuary: the Chesapeake Bay. Experiments using a coupled three‐dimensional hydrodynamic‐biogeochemical model highlight that, over the past three decades, the changes in the surface carbonate system of Chesapeake Bay have strong seasonal and spatial variability. The greatest surface pH and aragonite saturation state (ΩAR) reductions have occurred in the summer in the middle (mesohaline) Bay: −0.24 and −0.9 per 30 years, respectively, with increases in atmospheric CO2 and reductions in nitrate loading both being primary drivers. Reductions in nitrate loading have a strong seasonal influence on the carbonate system, with the most pronounced decadal decreases in pH and ΩAR occurring during the summer when primary production is strongly dependent on nutrient availability. Increases in riverine total alkalinity and dissolved inorganic carbon have raised surface pH in the upper oligohaline Bay, while other drivers such as atmospheric warming and input of acidified ocean water through the Bay mouth have had comparatively minor impacts on the estuarine carbonate system. This work has significant implications for estuarine ecosystem services, which are typically most sensitive to surface acidification in the spring and summer seasons.
Seawater pH, a measure of how acidic or basic water is, is a crucial water quality parameter influencing the growth and health of marine organisms, such as oysters, fishes and crabs. Decreasing pH, commonly referred to as acidification, is a severe environmental issue that has been exacerbated by human activities since the industrial revolution. In the open ocean, elevated atmospheric carbon dioxide is the key driver of acidification. However, in coastal environments the drivers are particularly complex due to changing human influences on land. In this study the primary drivers of acidification in the Chesapeake Bay over the past three decades are identified via the application of a three‐dimensional ecosystem model. Increased atmospheric CO2 concentrations and decreased terrestrial nutrient inputs are two primary drivers causing nearly equal reductions in pH in surface waters of the Bay. The pH reductions resulting from decreased nutrient loads indicate that the system is reverting back to more natural conditions when human‐induced nutrient inputs to the Bay were lower. As nutrient reduction efforts to improve coastal water quality continue in the future, controlling the emissions of anthropogenic CO2 globally becomes increasingly important for the shellfish industry and the ecosystem services it provides.

Decadal changes in estuarine surface pH and aragonite saturation state (ΩAR) exhibit large spatial and seasonal variability

In the upper Chesapeake Bay, changes in riverine alkalinity and dissolved inorganic carbon have increased surface pH in fall and spring

In the mid‐ and lower Bay, higher atmospheric CO2 and reduced nutrient loading have (nearly equally) reduced surface pH and ΩAR in summer

Decadal changes in estuarine surface pH and aragonite saturation state (ΩAR) exhibit large spatial and seasonal variability
In the upper Chesapeake Bay, changes in riverine alkalinity and dissolved inorganic carbon have increased surface pH in fall and spring
In the mid‐ and lower Bay, higher atmospheric CO2 and reduced nutrient loading have (nearly equally) reduced surface pH and ΩAR in summer

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Mechanisms Driving Decadal Changes in the Carbonate System of a Coastal Plain Estuary

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