Water mass evolution and general circulation of Baffin Bay: Observations from two shipboard surveys in 2021

Baffin Bay is an Arctic marginal sea connected to the North Atlantic via Davis Strait and the Labrador Sea. While the exchange of heat and freshwater through Davis Strait is known to strongly influence the subpolar North Atlantic, there are significant gaps in our understanding of the circulation and water mass distribution and transformation throughout Baffin Bay, in part due to limited direct velocity observations. In this study, high-resolution hydrographic, nutrient, oxygen isotope, and velocity data from two shipboard surveys in late-summer to early-fall 2021 are used to address these gaps. During the time period of observation, Baffin Bay was dominated by cold, fresh, nitrate-depleted Polar Water (PW) in the upper 300 m, with the coldest and freshest PW distributed along the western shelf and slope adjacent to Baffin Island. Only a small amount of warm and salty Atlantic-origin water was measured entering the southeastern bay at depth, which is diluted rapidly when passing through Davis Strait. Pacific-origin freshwater was dominant in the upper 200 m on the western side, with relatively small amounts of meteoric water on both sides of the bay. The circulation in Baffin Bay was generally cyclonic, consisting of a strong, surface-intensified western boundary current and a slower, weakly baroclinic eastern boundary current. Much of the eastern boundary current bifurcated to the west at the northern end of the Labrador Sea, and, as the remaining flow progressed through Davis Strait, it transitioned from surface-intensified to bottom-intensified. Basin-scale recirculation of the PW was documented using the shipboard data, which was also evident in the velocity field of an ocean reanalysis product for the same time period. Examination of the reanalysis fields from 1993 to 2021 indicates that the circulation in Baffin Bay was anomalously cyclonic during summer/fall 2021. Such basin-scale circulation anomalies can arise due to both the local wind stress curl pattern and remote wind forcing associated with the Arctic Oscillation index.