Kinematic Structure and Dynamics of the Denmark Strait Overflow from Ship-Based Observations

Lin, Peigen; Pickart, Robert S.; Jochumsen, Kerstin; Moore, G. W. K.; Valdimarsson, Héðinn; Fristedt, Tim; Pratt, Lawrence J.

doi:10.1175/jpo-d-20-0095.1

Cited by 11 publications

(12 citation statements)

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“…Previous studies of the EGC, and the AtOW that it transports, have mainly focused on the regions close to Fram and Denmark Straits (de Steur et al., 2009, 2014; Fahrbach et al., 2001; Foldvik et al., 1988; Harden et al., 2016; Håvik, Våge, et al., 2017; Håvik & Våge, 2018; Lin et al., 2020). Based on a long‐term (1997–2009) mooring array deployed south of Fram Strait (orange line in Figure 1), de Steur et al.…”

Section: Introductionmentioning

confidence: 99%

“…By analyzing a set of shipboard hydrographic‐velocity sections along the transect at Denmark Strait, Lin et al. (2020) estimated the total mean transport of AtOW to be 1.49 ± 0.10 Sv. For the regions between the two straits, the EGC and AtOW have been only sparsely observed.…”

Section: Introductionmentioning

confidence: 99%

“…Previous studies of the EGC, and the AtOW that it transports, have mainly focused on the regions close to Fram and Denmark Straits (de Steur et al, 2009(de Steur et al, , 2014Fahrbach et al, 2001;Foldvik et al, 1988;Harden et al, 2016;Lin et al, 2020). Based on a long-term (1997)(1998)(1999)(2000)(2001)(2002)(2003)(2004)(2005)(2006)(2007)(2008)(2009) mooring array deployed south of Fram Strait (orange line in Figure 1), de Steur et al (2014) found that the annual mean transport of the EGC is 8.7 Sv (1 Sv = 10 6 m 3 /s) at 78.8°N (including 3 Sv transported by the recirculation of the West Spitsbergen Current).…”

mentioning

confidence: 99%

“…Using a year-long mooring array deployed roughly 200 km north of Denmark Strait (purple line in Figure 1), Harden et al (2016) found that the annual transport of AtOW by the EGC is 2.54 ± 0.17 Sv. By analyzing a set of shipboard hydrographic-velocity sections along the transect at Denmark Strait, Lin et al (2020) estimated the total mean transport of AtOW to be 1.49 ± 0.10 Sv. For the regions between the two straits, the EGC and AtOW have been only sparsely observed.…”

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confidence: 99%

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Wintertime Water Mass Transformation in the Western Iceland and Greenland Seas

et al. 2021

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Hydrographic and velocity data from a 2018 winter survey of the western Iceland and Greenland Seas are used to investigate the ventilation of overflow water feeding Denmark Strait. We focus on the two general classes of overflow water: warm, saline Atlantic‐origin Overflow Water (AtOW) and cold, fresh Arctic‐origin Overflow Water (ArOW). The former is found predominantly within the East Greenland Current (EGC), while the latter resides in the interior of the Iceland and Greenland Seas. Progressing north to south, the properties of AtOW in the EGC are modified diapycnally during the winter, in contrast to summer when along‐isopycnal mixing dominates. The water column response to a 10‐days cold‐air outbreak was documented using repeat observations. During the event, the northerly winds pushed the freshwater cap of the EGC onshore, and convection modified the water at the seaward edge of the current. Lateral transfer of heat and salt from the core of AtOW in the EGC appears to have influenced some of this water mass transformation. The long‐term evolution of the mixed layers in the interior was investigated using a 1‐D mixing model. This suggests that, under strong atmospheric forcing, the densest component of ArOW can be ventilated in this region. Numerous anti‐cyclonic eddies spawned from the EGC were observed during the winter survey, revealing that these features can play differing roles in modifying/prohibiting the open‐ocean convection.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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confidence: 99%

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confidence: 99%

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Wintertime Water Mass Transformation in the Western Iceland and Greenland Seas

et al. 2021

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“…Values of the shear Rossby number exceed −1, which together with the strong negative relative vorticity on the anti‐cyclonic side of the ACC, lead to a region of negative total potential vorticity (Figures 11a). Such a condition can lead to symmetric instability (e.g., Lin, Pickart, Jochumsen, et al., 2020), which can reach finite amplitude in a matter of hours (Brearley et al., 2012). This implies that, when the ACC is strong and the associated density front is sharp, the outflow of the canyon is subject to strong mixing.…”

Section: Observational Evidence Of Vertical Pumping In Barrow Canyonmentioning

confidence: 99%

Physical Controls on the Macrofaunal Benthic Biomass in Barrow Canyon, Chukchi Sea

et al. 2021

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The Chukchi Sea is one of the most productive regions of the Arctic Ocean (Springer & McRoy, 1993), in part because of the high levels of nutrients advected through the Bering Strait (Grebmeier, Bluhm, et al., 2015). Furthermore, due to the recent decline in sea ice cover and higher percentage of thin first-year ice, light levels have increased which has led to even larger levels of annual production (Arrigo & van Dijken, 2011). Since the Chukchi shelf is an export-dominated regime, the large amount of carbon that reaches the seafloor supports robust levels of benthic activity (Grebmeier, Bluhm, et al., 2015). This in turn influences benthic-feeding higher trophic species such as walrus, whales, and sea birds (Grebmeier, Cooper, et al., 2006).The levels of benthic macrofaunal biomass vary regionally across the Chukchi shelf, with several well-defined "hot spots" (Figure 1). The broad area of enhanced biomass northwest of Bering Strait is associated with particularly high levels of nitrate that are advected into the region with the Anadyr water (Fang Abstract A region of exceptionally high macrofaunal benthic biomass exists in Barrow Canyon, implying a carbon export process that is locally concentrated. Here we offer an explanation for this benthic "hotspot" using shipboard data together with a set of dynamical equations. Repeat occupations of the Distributed Biological Observatory transect in Barrow Canyon reveal that when the northward flow is strong and the density front in the canyon is sharp, plumes of fluorescence and oxygen extend from the pycnocline to the seafloor in the vicinity of the hotspot. By solving the quasi-geostrophic omega equation with an analytical flow field fashioned after the observations, we diagnose the vertical velocity in the canyon. This reveals that, as the along stream flow converges into the canyon, it drives a secondary circulation cell with strong downwelling on the cyclonic side of the northward flow. The downwelling quickly advects material from the pycnocline to the seafloor in a vertical plume analogous to those seen in the observations. The plume occurs only when the phytoplankton reside in the pycnocline, since the near-surface vertical velocity is weak, also consistent with the observations. Using a wind-based proxy to represent the strength of the northward flow and hence the pumping, in conjunction with a satellitederived phytoplankton source function, we construct a time series of carbon supply to the bottom of Barrow Canyon.

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Separation of the Icelandic Coastal Current from the Reykjanes Peninsula

Whitney

2023

Estuarine, Coastal and Shelf Science

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Kinematic Structure and Dynamics of the Denmark Strait Overflow from Ship-Based Observations

Cited by 11 publications

References 51 publications

Wintertime Water Mass Transformation in the Western Iceland and Greenland Seas

Wintertime Water Mass Transformation in the Western Iceland and Greenland Seas

Physical Controls on the Macrofaunal Benthic Biomass in Barrow Canyon, Chukchi Sea

Separation of the Icelandic Coastal Current from the Reykjanes Peninsula

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