The southwestern South Atlantic Ocean is an important global sink of atmospheric carbon dioxide (CO 2 ), driven by increased primary productivity in a nearby region where oligotrophic warm currents converge with nutrient-rich cold waters. However, uncertainties remain regarding CO 2 dynamics and the role of physical processes in CO 2 uptake across this region. Here, we assess variations in surface partial pressure of CO 2 ( p CO 2 ) and air–sea CO 2 fluxes in the Southwest Atlantic, along a transect from the continental shelf to the open ocean at 34.5°S during austral autumn 2018 and winter 2019. High-resolution spatial measurements of the temperature, salinity, and molar fraction of surface CO 2 were conducted. In autumn 2018, the shelf region acted as a source of CO 2 to the atmosphere (median of 3.2 mmol CO 2 m -2 d -1 ), which was partially offset by a sink (median of –2.5 mmol CO 2 m -2 d -1 ) in the open ocean. In contrast, the entire transect in winter 2019 presented median CO 2 emissions of ~1.5 mmol CO 2 m -2 d -1 , which differs from climatological estimates. The spatial and seasonal variations in surface ocean p CO 2 were linked to variable hydrodynamic processes, including water masses and mesoscale structures. Our findings reveal that, in one of the most productive oceanic waters worldwide, p CO 2 may be influenced by distinct continental inputs (e.g., rivers, runoff, and groundwater discharge) and water masses (e.g., Tropical Water, Plata Plume Water and Subtropical Shelf Water). Therefore, the local hydrodynamic processes can modulate high spatial and seasonal variability in CO 2 exchange at the ocean–atmosphere interface, with potential implications for regional and global carbon budgets. General results, such as climatological, cannot fully capture the influence of regional upwelling and continental water input, which highlights the importance of high-resolution regional observations.
Albuquerque et al. (Wed,) studied this question.