Abstract
AbstractTime series data from a mooring in the center of Denmark Strait and a collection of shipboard hydrographic sections occupied across the sill are used to elucidate the mesoscale variability of the dense overflow water in the strait. Two dominant, reoccurring features are identified that are referred to as a bolus and a pulse. A bolus is a large, weakly stratified lens of overflow water associated with cyclonic rotation and a modest increase in along-stream speed of 0.1 m s−1. When a bolus passes through the strait the interface height of the overflow layer increases by 60 m, and the bottom temperature decreases by 0.4°C. By contrast, a pulse is characterized by anticyclonic rotation, a strong increase in along-stream speed of >0.25 m s−1, a decrease in interface height of 90 m, and no significant bottom temperature signal. It is estimated that, on average, boluses (pulses) pass through the strait every 3.4 (5.4) days with no seasonal signal to their frequency. Both features have the strongest along-stream signal in the overflow layer, while the strongest cross-stream velocities occur above the Denmark Strait overflow water (DSOW). In this sense neither feature can be characterized as a simple propagating eddy. Their dynamics appear to be similar to that ascribed to the mesoscale variability observed downstream in the deep western boundary current. Strong correlation of bottom temperatures between the mooring in Denmark Strait and a downstream array, together with a match in the frequency of occurrence of features at both locations, suggests a causal relationship between the mesoscale variability at the sill and that farther downstream.
Highlights
Denmark Strait overflow water (DSOW) is the largest and densest component of North Atlantic Deep Water (NADW) and contributes significantly to the deep limb of the global overturning circulation (Dickson and Brown 1994; Hansen and Østerhus 2007)
Our results demonstrate that mesoscale variability, with similar dynamics, does exist at the sill, which likely is related to the presence of the DSOW cyclones downstream
While the existence of the former feature has been known for decades, we quantified its temperature signal and determined that it is associated with cyclonic rotation and a modest increase in alongstream speed of approximately 0.1 m s21
Summary
Denmark Strait overflow water (DSOW) is the largest and densest component of North Atlantic Deep Water (NADW) and contributes significantly to the deep limb of the global overturning circulation (Dickson and Brown 1994; Hansen and Østerhus 2007). Látrabjarg transect, the potential density profiles from the CTD stations (no gridding was performed) were used to determine 1) the depth of the 27.8 kg m23 isopycnal, 2) the depth of the maximum vertical gradient of density, and 3) the depth of the maximum horizontal gradient of density at the deepest part of the Denmark Strait sill (i.e., where mooring DS1 was located). As seen, both the depth of maximum stratification (point 2) and maximum horizontal density gradient (point 3) agree relatively well with the depth of the 27.8 kg m23 isopycnal (the near-surface layer was excluded from this calculation). The maximum in horizontal density gradient is proportional to a maximum in the vertical shear of velocity; Fig. 2b justifies our use of ADCP shear to determine the overflow layer height. (We note that while the magnitude of the maximum vertical shear may be affected by the side-lobe contamination, its vertical location is not.)
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