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1. Seasonality of the Meridional Overturning Circulation in the subpolar North Atlantic

Author

Fu, Yao, Lozier, M. Susan, Biló, Tiago Carrilho, Bower, Amy S., Cunningham, Stuart A., Cyr, Frédéric, de Jong, M. Femke, deYoung, Brad, Drysdale, Lewis, Fraser, Neil, Fried, Nora, Furey, Heather H., Han, Guoqi, Handmann, Patricia, Holliday, N. Penny, Holte, James, Inall, Mark E., Johns, William E., Jones, Sam, Karstensen, Johannes, Li, Feili, Pacini, Astrid, Pickart, Robert S., Rayner, Darren, Straneo, Fiammetta, and Yashayaev, Igor

Published
2023
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2. The Pacific water flow branches in the eastern Chukchi Sea

Author

Pickart, Robert S., Lin, Peigen, Bahr, Frank, McRaven, Leah T., Huang, Jie, Pacini, Astrid, Arrigo, Kevin R., Ashjian, Carin J., Berchok, Catherine, Baumgartner, Mark F., Cho, Kyoung-Ho, Cooper, Lee W., Danielson, Seth L., Dasher, Douglas, Fuiwara, Amane, Gann, Jeanette, Grebmeier, Jacqueline M., He, Jianfeng, Hirawake, Toru, Itoh, Motoyo, Juranek, Lauren, Kikuchi, Takashi, Moore, G.W.K., Napp, Jeff, John Nelson, R., Nishino, Shigeto, Statscewich, Hank, Stabeno, Phyllis, Stafford, Kathleen M., Ueno, Hiromichi, Vagle, Svein, Weingartner, Thomas J., Williams, Bill, and Zimmermann, Sarah

Published
2023
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3. Postdoc Perspectives on Leadership and Matters of Equity and Inclusion in Polar Science.

Author

Goliber, Sophie, Coenen, Jason, Fair, Heather, Szesciorka, Angela R., Schulz, Kirstin, Harning, David J., Fernando, Benjamin, Ksenofontov, Stanislav Saas, Pacini, Astrid, Rivera, Marisol Juarez, Calmer, Radiance, Conroy, John A., Doting, Eva Lisa, Bergelin, Marie, Dunmire, Devon, Sánchez Montes, Maria Luisa, Ravelo, Alexandra M., Sledd, Anne, Stinchcomb, Taylor R., and Tibbett, Emily J.

Published
2024
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5. Vertical Carbon Export During a Phytoplankton Bloom in the Chukchi Sea: Physical Setting and Frontal Subduction.

Author

Pickart, Robert S., Spall, Michael A., Bahr, Frank, Lago, Loreley, Lin, Peigen, Pacini, Astrid, Mills, Matthew, Huang, Jie, Arrigo, Kevin R., van Dijken, Gert, McRaven, Leah T., and Roberts, Steven

Subjects
BAROCLINICITY, SUBDUCTION, PLANKTON blooms, CHLOROPHYLL spectra, WATERFRONTS, ALGAL blooms
Abstract

In order to quantify pelagic‐benthic coupling on high‐latitude shelves, it is imperative to identify the different physical mechanisms by which phytoplankton are exported to the sediments. In June–July 2023, a field program documented the evolution of an under‐ice phytoplankton bloom on the northeast Chukchi shelf. Here, we use in situ data from the cruise, a simple numerical model, historical water column data, and ocean reanalysis fields to characterize the physical setting and describe the dynamically driven vertical export of chlorophyll associated with the bloom. A water mass front separating cold, high‐nutrient winter water in the north and warmer summer waters to the south—roughly coincident with the ice edge—supported a baroclinic jet which is part of the Central Channel flow branch that veers eastward toward Barrow Canyon. A plume of high chlorophyll fluorescence extending from the near‐surface bloom in the winter water downwards along the front was measured throughout the cruise. Using a passive tracer to represent phytoplankton in the model, it was demonstrated that the plume is the result of subduction due to baroclinic instability of the frontal jet. This process, in concert with the gravitational sinking, pumps the chlorophyll downwards an order of magnitude faster than gravitational sinking alone. Particle tracking using the ocean reanalysis fields reveals that a substantial portion of the chlorophyll away from the front is advected off of the northeast Chukchi shelf before reaching the bottom. This highlights the importance of the frontal subduction process for delivering carbon to the sea floor. Plain Language Summary: The Chukchi Sea shelf north of Bering Strait is known to experience some of the largest phytoplankton blooms in the Arctic Ocean. In 2023, a field program was carried out to quantify aspects of the early summer bloom, with an emphasis on characterizing how the phytoplankton biomass from the bloom is exported to the sea floor. A large bloom was measured under the pack ice in very cold, high‐nutrient water, just north of warmer, ice‐free waters. The front separating the warm and cold waters supported a current flowing eastward, which is one of the main flow pathways on the Chukchi shelf. A plume of high chlorophyll fluorescence extending from the near‐surface bloom downwards along the front was measured throughout the cruise. We demonstrate that this vertical pumping was due to a dynamical process associated with the current which resulted in much faster downward export of phytoplankton than gravitational sinking alone. Tracking the fate of particles on the northeast Chukchi shelf using an ocean simulation revealed that much of the phytoplankton biomass away from the front is carried off the shelf before reaching the bottom. This highlights the importance of the frontal process for delivering chlorophyll to the sea floor. Key Points: An under‐ice phytoplankton bloom developed during June–July in the northeast Chukchi Sea within the Central Channel flow branchA plume of chlorophyll fluorescence extending downwards from the bloom along the current's water mass front was continually presentA simple numerical model demonstrates that the plume is the result of baroclinic instability of the frontal jet [ABSTRACT FROM AUTHOR]

Published
2024
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7. Mean and Seasonal Circulation of the Eastern Chukchi Sea From Moored Timeseries in 2013–2014

Author

Tian, Fei, Pickart, Robert S., Lin, Peigen, Pacini, Astrid, Moore, G. W. K., Stabeno, Phyllis, Weingartner, Thomas, Itoh, Motoyo, Kikuchi, Takashi, Dobbins, Elizabeth, Bell, Shaun, Woodgate, Rebecca A., Danielson, Seth L., Wang, Zhaomin, Tian, Fei, Pickart, Robert S., Lin, Peigen, Pacini, Astrid, Moore, G. W. K., Stabeno, Phyllis, Weingartner, Thomas, Itoh, Motoyo, Kikuchi, Takashi, Dobbins, Elizabeth, Bell, Shaun, Woodgate, Rebecca A., Danielson, Seth L., and Wang, Zhaomin

Abstract

From late-summer 2013 to late-summer 2014, a total of 20 moorings were maintained on the eastern Chukchi Sea shelf as part of five independent field programs. This provided the opportunity to analyze an extensive set of timeseries to obtain a broad view of the mean and seasonally varying hydrography and circulation over the course of the year. Year-long mean bottom temperatures reflected the presence of the strong coastal circulation pathway, while mean bottom salinities were influenced by polynya/lead activity along the coast. The timing of the warm water appearance in spring/summer is linked to advection along the various flow pathways. The timing of the cold water appearance in fall/winter was not reflective of advection nor related to the time of freeze-up. Near the latitude of Barrow Canyon, the cold water was accompanied by freshening. A one-dimensional mixed-layer model demonstrates that wind mixing, due to synoptic storms, overturns the water column resulting in the appearance of the cold water. The loitering pack ice in the region, together with warm southerly winds, melted ice and provided an intermittent source of fresh water that was mixed to depth according to the model. Farther north, the ambient stratification prohibits wind-driven overturning, hence the cold water arrives from the south. The circulation during the warm and cold months of the year is different in both strength and pattern. Our study highlights the multitude of factors involved in setting the seasonal cycle of hydrography and circulation on the Chukchi shelf.

Published
2022

9. Structure, variability, and dynamics of the West Greenland Boundary Current System

Author

Pickart, Robert S., Pacini, Astrid, Pickart, Robert S., and Pacini, Astrid

Abstract

Submitted in partial fulfillment of the requirements for the degree of Doctor of Philosophy at the Massachusetts Institute of Technology and the Woods Hole Oceanographic Institution February 2022., The ventilation of intermediate waters in the Labrador Sea has important implications for the strength of the Atlantic Meridional Overturning Circulation. Boundary current-interior interactions regulate the exchange of properties between the slope and the basin, which in turn regulates the magnitude of interior convection and the export of ventilated waters from the subpolar gyre. This thesis characterizes theWest Greenland Boundary Current System near Cape Farewell across a range of spatio-temporal scales. The boundary current system is composed of three velocity cores: (1) the West Greenland Coastal Current (WGCC), transporting Greenland and Arctic meltwaters on the shelf; (2) the West Greenland Current (WGC), which advects warm, saline Atlantic-origin water at depth, meltwaters at the surface, and newly-ventilated Labrador Sea Water (LSW); and (3) the Deep Western Boundary Current, which carries dense overflow waters ventilated in the Nordic Seas. The seasonal presence of the LSW and Atlantic-origin water are dictated by air-sea buoyancy forcing, while the seasonality of the WGCC is governed by remote wind forcing and the propagation of coastally trapped waves from East Greenland. Using mooring data and hydrographic surveys, we demonstrate mid-depth intensified cyclones generated at Denmark Strait are found offshore of the WGC and enhance the overflow water transport at synoptic timescales. Using mooring, hydrographic, and satellite data, we demonstrate that the WGC undergoes extensive meandering due to baroclinic instability that is enhanced in winter due to LSW formation adjacent to the current. This leads to the production of small-scale, anticyclonic eddies that can account for the entirety of wintertime heat loss within the Labrador Sea. The meanders are shown to trigger the formation of Irminger Rings downstream. Using mooring, hydrographic, atmospheric, and Lagrangian data, and a mixing model, we find that strong atmospheric storms known as forward tip jet, The work in this dissertation was funded by the National Science Foundation grants OCE-1259618 and OCE-1756361.

Published
2021

10. Cyclonic eddies in the West Greenland boundary current system

Author

Pacini, Astrid, Pickart, Robert S., Le Bras, Isabela A., Straneo, Fiammetta, Holliday, N.P., Spall, M.A., Pacini, Astrid, Pickart, Robert S., Le Bras, Isabela A., Straneo, Fiammetta, Holliday, N.P., and Spall, M.A.

Abstract

The boundary current system in the Labrador Sea plays an integral role in modulating convection in the interior basin. Four years of mooring data from the eastern Labrador Sea reveal persistent mesoscale variability in the West Greenland boundary current. Between 2014 and 2018, 197 mid-depth intensified cyclones were identified that passed the array near the 2000 m isobath. In this study, we quantify these features and show that they are the downstream manifestation of Denmark Strait Overflow Water (DSOW) cyclones. A composite cyclone is constructed revealing an average radius of 9 km, maximum azimuthal speed of 24 cm/s, and a core propagation velocity of 27 cm/s. The core propagation velocity is significantly smaller than upstream near Denmark Strait, allowing them to trap more water. The cyclones transport a 200-m thick lens of dense water at the bottom of the water column, and increase the transport of DSOW in the West Greenland boundary current by 17% relative to the background flow. Only a portion of the features generated at Denmark Strait make it to the Labrador Sea, implying that the remainder are shed into the interior Irminger Sea, are retroflected at Cape Farewell, or dissipate. A synoptic shipboard survey east of Cape Farewell, conducted in summer 2020, captured two of these features which shed further light on their structure and timing. This is the first time DSOW cyclones have been observed in the Labrador Sea—a discovery that could have important implications for interior stratification.

Published
2021

11. Subpolar North Atlantic western boundary density anomalies and the Meridional Overturning Circulation

Author

Li, Feili, Lozier, M. Susan, Bacon, Sheldon, Bower, Amy S., Cunningham, Stuart A., de Jong, Marieke F., deYoung, Brad, Fraser, Neil, Fried, Nora, Han, Guoqi, Holliday, Naomi Penny, Holte, James W., Houpert, Loïc, Inall, Mark E., Johns, William E., Jones, Sam, Johnson, Clare, Karstensen, Johannes, Le Bras, Isabela A., Lherminier, Pascale, Lin, Xiaopei, Mercier, Herlé, Oltmanns, Marilena, Pacini, Astrid, Petit, Tillys, Pickart, Robert S., Rayner, Darren, Straneo, Fiamma, Thierry, Virginie, Visbeck, Martin, Yashayaev, Igor, Zhou, Chun, Li, Feili, Lozier, M. Susan, Bacon, Sheldon, Bower, Amy S., Cunningham, Stuart A., de Jong, Marieke F., deYoung, Brad, Fraser, Neil, Fried, Nora, Han, Guoqi, Holliday, Naomi Penny, Holte, James W., Houpert, Loïc, Inall, Mark E., Johns, William E., Jones, Sam, Johnson, Clare, Karstensen, Johannes, Le Bras, Isabela A., Lherminier, Pascale, Lin, Xiaopei, Mercier, Herlé, Oltmanns, Marilena, Pacini, Astrid, Petit, Tillys, Pickart, Robert S., Rayner, Darren, Straneo, Fiamma, Thierry, Virginie, Visbeck, Martin, Yashayaev, Igor, and Zhou, Chun

Abstract

© The Author(s), 2021. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Li, F., Lozier, M. S., Bacon, S., Bower, A. S., Cunningham, S. A., de Jong, M. F., DeYoung, B., Fraser, N., Fried, N., Han, G., Holliday, N. P., Holte, J., Houpert, L., Inall, M. E., Johns, W. E., Jones, S., Johnson, C., Karstensen, J., Le Bras, I. A., P. Lherminier, X. Lin, H. Mercier, M. Oltmanns, A. Pacini, T. Petit, R. S. Pickart, D. Rayner, F. Straneo, V. Thierry, M. Visbeck, I. Yashayaev & Zhou, C. Subpolar North Atlantic western boundary density anomalies and the Meridional Overturning Circulation. Nature Communications, 12(1), (2021): 3002, https://doi.org/10.1038/s41467-021-23350-2., Changes in the Atlantic Meridional Overturning Circulation, which have the potential to drive societally-important climate impacts, have traditionally been linked to the strength of deep water formation in the subpolar North Atlantic. Yet there is neither clear observational evidence nor agreement among models about how changes in deep water formation influence overturning. Here, we use data from a trans-basin mooring array (OSNAP—Overturning in the Subpolar North Atlantic Program) to show that winter convection during 2014–2018 in the interior basin had minimal impact on density changes in the deep western boundary currents in the subpolar basins. Contrary to previous modeling studies, we find no discernable relationship between western boundary changes and subpolar overturning variability over the observational time scales. Our results require a reconsideration of the notion of deep western boundary changes representing overturning characteristics, with implications for constraining the source of overturning variability within and downstream of the subpolar region., We acknowledge funding from the Physical Oceanography Program of the U.S. National Science Foundation (OCE-1259398, OCE-1756231, OCE-1948335); the U.K. Natural Environment Research Council (NERC) National Capability programs the Extended Ellett Line and CLASS (NE/R015953/1), and NERC grants UK-OSNAP (NE/K010875/1, NE/K010875/2, NE/K010700/1) and U.K. OSNAP Decade (NE/T00858X/1, NE/T008938/1). Additional support was received from the European Union 7th Framework Program (FP7 2007-2013) under grant 308299 (NACLIM), the Horizon 2020 research and innovation program under grants 727852 (Blue-Action), 862626 (EuroSea). We also acknowledge support from the Royal Netherlands Institute for Sea Research, the Surface Water and Ocean Topography-Canada (SWOT-C), Canadian Space Agency, the Aquatic Climate Change Adaptation Services Program (ACCASP), Fisheries and Oceans Canada, an Natural Sciences and Engineering Research Council of Canada (NSERC) Discovery Grant, and from the China’s national key research and development projects (2016YFA0601803), the National Natural Science Foundation of China (41925025) and the Fundamental Research Funds for the Central Universities (201424001). Support for the 53°N array by the RACE program of the German Ministry BMBF is acknowledged, as is the contribution from Fisheries and Oceans Canada’s Atlantic Zone Monitoring Program.

Published
2021

12. Mean and seasonal circulation of the eastern Chukchi Sea from moored timeseries in 2013-2014

Author

Tian, Fei, Pickart, Robert S., Lin, Peigen, Pacini, Astrid, Moore, G. W. K., Stabeno, Phyllis J., Weingartner, Thomas J., Itoh, Motoyo, Kikuchi, Takashi, Dobbins, Elizabeth, Bell, Shaun, Woodgate, Rebecca, Danielson, Seth L., Wang, Zhaomin, Tian, Fei, Pickart, Robert S., Lin, Peigen, Pacini, Astrid, Moore, G. W. K., Stabeno, Phyllis J., Weingartner, Thomas J., Itoh, Motoyo, Kikuchi, Takashi, Dobbins, Elizabeth, Bell, Shaun, Woodgate, Rebecca, Danielson, Seth L., and Wang, Zhaomin

Abstract

Author Posting. © American Geophysical Union, 2021. This article is posted here by permission of American Geophysical Union for personal use, not for redistribution. The definitive version was published in Journal of Geophysical Research: Oceans 126(5), (2021): e2020JC016863, https://doi.org/10.1029/2020JC016863., From late-summer 2013 to late-summer 2014, a total of 20 moorings were maintained on the eastern Chukchi Sea shelf as part of five independent field programs. This provided the opportunity to analyze an extensive set of timeseries to obtain a broad view of the mean and seasonally varying hydrography and circulation over the course of the year. Year-long mean bottom temperatures reflected the presence of the strong coastal circulation pathway, while mean bottom salinities were influenced by polynya/lead activity along the coast. The timing of the warm water appearance in spring/summer is linked to advection along the various flow pathways. The timing of the cold water appearance in fall/winter was not reflective of advection nor related to the time of freeze-up. Near the latitude of Barrow Canyon, the cold water was accompanied by freshening. A one-dimensional mixed-layer model demonstrates that wind mixing, due to synoptic storms, overturns the water column resulting in the appearance of the cold water. The loitering pack ice in the region, together with warm southerly winds, melted ice and provided an intermittent source of fresh water that was mixed to depth according to the model. Farther north, the ambient stratification prohibits wind-driven overturning, hence the cold water arrives from the south. The circulation during the warm and cold months of the year is different in both strength and pattern. Our study highlights the multitude of factors involved in setting the seasonal cycle of hydrography and circulation on the Chukchi shelf., The authors are extremely grateful to all of these individuals, and to the funding agencies that supported the respective field programs: The Bureau of Ocean Energy Management; The National Oceanic and Atmospheric Administration; The National Science Foundation; and The Japanese Agency for Marine-Earth Science and Technology. Support for this analysis was provided by the following grants: National Oceanic and Atmospheric Administration grant NA14OAR4320158; National Science Foundation grants PLR-1504333, OPP-1733564, PLR-1758565; North Pacific Research Board grants A91-99a and A91-00a; Chinese Arctic and Antarctic grant CXPT2020009; Natural Sciences and Engineering Research Council of Canada.

Published
2021

13. Mean conditions and seasonality of the West Greenland boundary current system near Cape Farewell

Author

Pacini, Astrid, Pickart, Robert S., Bahr, Frank B., Torres, Daniel J., Ramsey, Andree L., Holte, James W., Karstensen, Johannes, Oltmanns, Marilena, Straneo, Fiamma, Le Bras, Isabela Astiz, Moore, G. W. K., de Jong, Marieke Femke, Pacini, Astrid, Pickart, Robert S., Bahr, Frank B., Torres, Daniel J., Ramsey, Andree L., Holte, James W., Karstensen, Johannes, Oltmanns, Marilena, Straneo, Fiamma, Le Bras, Isabela Astiz, Moore, G. W. K., and de Jong, Marieke Femke

Abstract

Author Posting. © American Meteorological Society, 2020. This article is posted here by permission of American Meteorological Society for personal use, not for redistribution. The definitive version was published in Journal of Physical Oceanography 50(10), (2020): 2849-2871, https://doi.org/10.1175/JPO-D-20-0086.1., The structure, transport, and seasonal variability of the West Greenland boundary current system near Cape Farewell are investigated using a high-resolution mooring array deployed from 2014 to 2018. The boundary current system is comprised of three components: the West Greenland Coastal Current, which advects cold and fresh Upper Polar Water (UPW); the West Greenland Current, which transports warm and salty Irminger Water (IW) along the upper slope and UPW at the surface; and the Deep Western Boundary Current, which advects dense overflow waters. Labrador Sea Water (LSW) is prevalent at the seaward side of the array within an offshore recirculation gyre and at the base of the West Greenland Current. The 4-yr mean transport of the full boundary current system is 31.1 ± 7.4 Sv (1 Sv ≡ 106 m3 s−1), with no clear seasonal signal. However, the individual water mass components exhibit seasonal cycles in hydrographic properties and transport. LSW penetrates the boundary current locally, through entrainment/mixing from the adjacent recirculation gyre, and also enters the current upstream in the Irminger Sea. IW is modified through air–sea interaction during winter along the length of its trajectory around the Irminger Sea, which converts some of the water to LSW. This, together with the seasonal increase in LSW entering the current, results in an anticorrelation in transport between these two water masses. The seasonality in UPW transport can be explained by remote wind forcing and subsequent adjustment via coastal trapped waves. Our results provide the first quantitatively robust observational description of the boundary current in the eastern Labrador Sea., A.P., R.S.P., F.B., D.J.T., and A.L.R. were funded by Grants OCE-1259618 and OCE-1756361 from the National Science Foundation. I.L.B, F.S., and J.H. were supported by U.S. National Science Foundation Grants OCE-1258823 and OCE-1756272. Mooring data from MA2 was funded by the European Union 7th Framework Programme (FP7 2007-2013) under Grant 308299 (NACLIM) and the Horizon 2020 research and innovation program under Grant 727852 (Blue-Action). J.K. and M.O. acknowledge EU Horizon 2020 funding Grants 727852 (Blue-action) and 862626 (EuroSea) and from the German Ministry of Research and Education (RACE Program). G.W.K.M. acknowledges funding from the Natural Sciences and Engineering Research Council.

Published
2021

14. Mean and Seasonal Circulation of the Eastern Chukchi Sea From Moored Timeseries in 2013–2014

Author

Tian, Fei, primary, Pickart, Robert S., additional, Lin, Peigen, additional, Pacini, Astrid, additional, Moore, G. W. K., additional, Stabeno, Phyllis, additional, Weingartner, Thomas, additional, Itoh, Motoyo, additional, Kikuchi, Takashi, additional, Dobbins, Elizabeth, additional, Bell, Shaun, additional, Woodgate, Rebecca A., additional, Danielson, Seth L., additional, and Wang, Zhaomin, additional

Published
2021
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16. Mean Conditions and Seasonality of the West Greenland Boundary Current System near Cape Farewell

Author

Pacini, Astrid, primary, Pickart, Robert S., additional, Bahr, Frank, additional, Torres, Daniel J., additional, Ramsey, Andrée L., additional, Holte, James, additional, Karstensen, Johannes, additional, Oltmanns, Marilena, additional, Straneo, Fiammetta, additional, Le Bras, Isabela Astiz, additional, Moore, G. W. K., additional, and Femke de Jong, M., additional

Published
2020
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17. The Iceland Greenland Seas Project

Author

Renfrew, Ian A., Pickart, Robert S., Vage, Kjetil, Moore, G. W. K., Bracegirde, Thomas J., Elvidge, Andrew D., Jeansson, Emil, Lachlan-Cope, Thomas, McRaven, Leah T., Papritz, Lukas, Reuder, Joachim, Sodemann, Harald, Terpstra, Annick, Waterman, Stephanie N., Valdimarsson, Héðinn, Weiss, Albert, Almansi, Mattia, Bahr, Frank B., Brakstad, Ailin, Barrell, Christopher, Brooke, Jennifer K., Brooks, Barbara J., Brooks, Ian M., Brooks, Malcolm E., Bruvik, Erik Magnus, Duscha, Christiane, Fer, Ilker, Golid, H. M., Hallerstig, M., Hessevik, Idar, Huang, Jie, Houghton, Leah A., Jonsson, Steingrimur, Jonassen, Marius, Jackson, K., Kvalsund, K., Kolstad, Erik W., Konstali, K., Kristiansen, Jorn, Ladkin, Russell, Lin, Peigen, Macrander, Andreas, Mitchell, Alexandra, Olafsson, H., Pacini, Astrid, Payne, Chris, Palmason, Bolli, Perez-Hernandez, M. Dolores, Peterson, Algot K., Petersen, Guðrún N., Pisareva, Maria N., Pope, James O., Seidl, Andrew D., Semper, Stefanie, Sergeev, Denis, Skjelsvik, Silje, Søiland, Henrik, Smith, D., Spall, Michael A., Spengler, Thomas, Touzeau, Alexandra, Tupper, George H., Weng, Y., Williams, Keith D., Yang, Xiaohau, Zhou, Shenjie, Renfrew, Ian A., Pickart, Robert S., Vage, Kjetil, Moore, G. W. K., Bracegirde, Thomas J., Elvidge, Andrew D., Jeansson, Emil, Lachlan-Cope, Thomas, McRaven, Leah T., Papritz, Lukas, Reuder, Joachim, Sodemann, Harald, Terpstra, Annick, Waterman, Stephanie N., Valdimarsson, Héðinn, Weiss, Albert, Almansi, Mattia, Bahr, Frank B., Brakstad, Ailin, Barrell, Christopher, Brooke, Jennifer K., Brooks, Barbara J., Brooks, Ian M., Brooks, Malcolm E., Bruvik, Erik Magnus, Duscha, Christiane, Fer, Ilker, Golid, H. M., Hallerstig, M., Hessevik, Idar, Huang, Jie, Houghton, Leah A., Jonsson, Steingrimur, Jonassen, Marius, Jackson, K., Kvalsund, K., Kolstad, Erik W., Konstali, K., Kristiansen, Jorn, Ladkin, Russell, Lin, Peigen, Macrander, Andreas, Mitchell, Alexandra, Olafsson, H., Pacini, Astrid, Payne, Chris, Palmason, Bolli, Perez-Hernandez, M. Dolores, Peterson, Algot K., Petersen, Guðrún N., Pisareva, Maria N., Pope, James O., Seidl, Andrew D., Semper, Stefanie, Sergeev, Denis, Skjelsvik, Silje, Søiland, Henrik, Smith, D., Spall, Michael A., Spengler, Thomas, Touzeau, Alexandra, Tupper, George H., Weng, Y., Williams, Keith D., Yang, Xiaohau, and Zhou, Shenjie

Abstract

© The Author(s), 2019. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Renfrew, I. A., Pickart, R. S., Vage, K., Moore, G. W. K., Bracegirdle, T. J., Elvidge, A. D., Jeansson, E., Lachlan-Cope, T., McRaven, L. T., Papritz, L., Reuder, J., Sodemann, H., Terpstra, A., Waterman, S., Valdimarsson, H., Weiss, A., Almansi, M., Bahr, F., Brakstad, A., Barrell, C., Brooke, J. K., Brooks, B. J., Brooks, I. M., Brooks, M. E., Bruvik, E. M., Duscha, C., Fer, I., Golid, H. M., Hallerstig, M., Hessevik, I., Huang, J., Houghton, L., Jonsson, S., Jonassen, M., Jackson, K., Kvalsund, K., Kolstad, E. W., Konstali, K., Kristiansen, J., Ladkin, R., Lin, P., Macrander, A., Mitchell, A., Olafsson, H., Pacini, A., Payne, C., Palmason, B., Perez-Hernandez, M. D., Peterson, A. K., Petersen, G. N., Pisareva, M. N., Pope, J. O., Seidl, A., Semper, S., Sergeev, D., Skjelsvik, S., Soiland, H., Smith, D., Spall, M. A., Spengler, T., Touzeau, A., Tupper, G., Weng, Y., Williams, K. D., Yang, X., & Zhou, S. The Iceland Greenland Seas Project. Bulletin of the American Meteorological Society, 100(9), (2019): 1795-1817, doi:10.1175/BAMS-D-18-0217.1., The Iceland Greenland Seas Project (IGP) is a coordinated atmosphere–ocean research program investigating climate processes in the source region of the densest waters of the Atlantic meridional overturning circulation. During February and March 2018, a field campaign was executed over the Iceland and southern Greenland Seas that utilized a range of observing platforms to investigate critical processes in the region, including a research vessel, a research aircraft, moorings, sea gliders, floats, and a meteorological buoy. A remarkable feature of the field campaign was the highly coordinated deployment of the observing platforms, whereby the research vessel and aircraft tracks were planned in concert to allow simultaneous sampling of the atmosphere, the ocean, and their interactions. This joint planning was supported by tailor-made convection-permitting weather forecasts and novel diagnostics from an ensemble prediction system. The scientific aims of the IGP are to characterize the atmospheric forcing and the ocean response of coupled processes; in particular, cold-air outbreaks in the vicinity of the marginal ice zone and their triggering of oceanic heat loss, and the role of freshwater in the generation of dense water masses. The campaign observed the life cycle of a long-lasting cold-air outbreak over the Iceland Sea and the development of a cold-air outbreak over the Greenland Sea. Repeated profiling revealed the immediate impact on the ocean, while a comprehensive hydrographic survey provided a rare picture of these subpolar seas in winter. A joint atmosphere–ocean approach is also being used in the analysis phase, with coupled observational analysis and coordinated numerical modeling activities underway., The IGP has received funding from the U.S. National Science Foundation: Grant OCE-1558742; the U.K.’s Natural Environment Research Council: AFIS (NE/N009754/1); the Research Council of Norway: MOCN (231647), VENTILATE (229791), SNOWPACE (262710) and FARLAB (245907); and the Bergen Research Foundation (BFS2016REK01). We thank all those involved in the field work associated with the IGP, particularly the officers and crew of the Alliance, and the operations staff of the aircraft campaign.

Published
2020

18. Mean conditions and seasonality of the West Greenland boundary current system near Cape Farewell

Author

Pacini, Astrid, Pickart, Robert S., Bahr, Frank, Torres, Daniel J., Ramsey, Andrée L., Holte, James, Karstensen, Johannes, Oltmanns, Marilena, Straneo, Fiammetta, Le Bras, Isabela Astiz, Moore, G. W. K., Femke de Jong, M., Pacini, Astrid, Pickart, Robert S., Bahr, Frank, Torres, Daniel J., Ramsey, Andrée L., Holte, James, Karstensen, Johannes, Oltmanns, Marilena, Straneo, Fiammetta, Le Bras, Isabela Astiz, Moore, G. W. K., and Femke de Jong, M.

Abstract

The structure, transport, and seasonal variability of the West Greenland boundary current system near Cape Farewell are investigated using a high-resolution mooring array deployed from 2014 to 2018. The boundary current system is comprised of three components: the West Greenland Coastal Current, which advects cold and fresh Upper Polar Water (UPW); the West Greenland Current, which transports warm and salty Irminger Water (IW) along the upper slope and UPW at the surface; and the Deep Western Boundary Current, which advects dense overflow waters. Labrador Sea Water (LSW) is prevalent at the seaward side of the array within an offshore recirculation gyre and at the base of the West Greenland Current. The 4-yr mean transport of the full boundary current system is 31.1 ± 7.4 Sv (1 Sv ≡ 106 m3 s−1), with no clear seasonal signal. However, the individual water mass components exhibit seasonal cycles in hydrographic properties and transport. LSW penetrates the boundary current locally, through entrainment/mixing from the adjacent recirculation gyre, and also enters the current upstream in the Irminger Sea. IW is modified through air–sea interaction during winter along the length of its trajectory around the Irminger Sea, which converts some of the water to LSW. This, together with the seasonal increase in LSW entering the current, results in an anticorrelation in transport between these two water masses. The seasonality in UPW transport can be explained by remote wind forcing and subsequent adjustment via coastal trapped waves. Our results provide the first quantitatively robust observational description of the boundary current in the eastern Labrador Sea.

Published
2020

19. Characteristics and transformation of Pacific winter water on the Chukchi Sea shelf in late spring

Author

Pacini, Astrid, Moore, G. W. K., Pickart, Robert S., Nobre, Carolina, Bahr, Frank B., Vage, Kjetil, Arrigo, Kevin R., Pacini, Astrid, Moore, G. W. K., Pickart, Robert S., Nobre, Carolina, Bahr, Frank B., Vage, Kjetil, and Arrigo, Kevin R.

Abstract

Author Posting. © American Geophysical Union, 2019. This article is posted here by permission of American Geophysical Union for personal use, not for redistribution. The definitive version was published in Journal of Geophysical Research-Oceans 124 (2019): 7153– 7177, doi: 10.1029/2019JC015261., Data from a late spring survey of the northeast Chukchi Sea are used to investigate various aspects of newly ventilated winter water (NVWW). More than 96% of the water sampled on the shelf was NVWW, the saltiest (densest) of which tended to be in the main flow pathways on the shelf. Nearly all of the hydrographic profiles on the shelf displayed a two‐layer structure, with a surface mixed layer and bottom boundary layer separated by a weak density interface (on the order of 0.02 kg/m3). Using a polynya model to drive a one‐dimensional mixing model, it was demonstrated that, on average, the profiles would become completely homogenized within 14–25 hr when subjected to the March and April heat fluxes. A subset of the profiles would become homogenized when subjected to the May heat fluxes. Since the study domain contained numerous leads within the pack ice—many of them refreezing—and since some of the measured profiles were vertically uniform in density, this suggests that NVWW is formed throughout the Chukchi shelf via convection within small openings in the ice. This is consistent with the result that the salinity signals of the NVWW along the central shelf pathway cannot be explained solely by advection from Bering Strait or via modification within large polynyas. The local convection would be expected to stir nutrients into the water column from the sediments, which explains the high nitrate concentrations observed throughout the shelf. This provides a favorable initial condition for phytoplankton growth on the Chukchi shelf., The authors are indebted to Commanding Officer John Reeves, Executive Officer Gregory Stanclik, Operations Officer Jacob Cass, and the entire crew of the USCGC Healy for their hard work and dedication in making the SUBICE cruise a success. We also acknowledge Scott Hiller for his assistance with Healy's meteorological data. We thank an anonymous reviewer for helpful input that improved the paper. Funding for A. P., R. P., C. N., and F. B. was provided by the National Science Foundation (NSF) under grant PLR‐1303617. K. M. was funded by the Natural Sciences and Engineering Research Council of Canada. K. V. acknowledges the Bergen Research Foundation under Grant BFS2016REK01. K. A. was supported by the NSF grant PLR‐1304563. The CTD and shipboard ADCP data are available from https://www.rvdata.us/search/cruise/HLY1401, and the nutrient data can be accessed from https://arcticdata.io/catalog/view/doi:10.18739/A2RG3Z and http://ocean.stanford.edu/subice/. The shipboard meteorological data reside at http://ocean.stanford.edu/subice/., 2020-04-14

Published
2020

22. Growth and steady state of the Patagonian Andes

Author

Colwyn, David Auerbach, primary, Brandon, Mark T., additional, Hren, Michael T., additional, Hourigan, Jeremy, additional, Pacini, Astrid, additional, Cosgrove, Martha G., additional, Midzik, Maya, additional, Garreaud, René D., additional, and Metzger, Christine, additional

Published
2019
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23. Pacific abyssal transport and mixing: Through the Samoan Passage versus around the Manihiki Plateau

Author

Pratt, Lawrence J., Voet, Gunnar, Pacini, Astrid, Tan, Shuwen, Alford, Matthew H., Carter, Glenn S., Girton, James B., Menemenlis, Dimitris, Pratt, Lawrence J., Voet, Gunnar, Pacini, Astrid, Tan, Shuwen, Alford, Matthew H., Carter, Glenn S., Girton, James B., and Menemenlis, Dimitris

Abstract

Author Posting. © American Meteorological Society, 2019. This article is posted here by permission of American Meteorological Society for personal use, not for redistribution. The definitive version was published in Journal of Physical Oceanography 49(6), (2019): 1577-1592, doi:10.1175/JPO-D-18-0124.1., The main source feeding the abyssal circulation of the North Pacific is the deep, northward flow of 5–6 Sverdrups (Sv; 1 Sv ≡ 106 m3 s−1) through the Samoan Passage. A recent field campaign has shown that this flow is hydraulically controlled and that it experiences hydraulic jumps accompanied by strong mixing and dissipation concentrated near several deep sills. By our estimates, the diapycnal density flux associated with this mixing is considerably larger than the diapycnal flux across a typical isopycnal surface extending over the abyssal North Pacific. According to historical hydrographic observations, a second source of abyssal water for the North Pacific is 2.3–2.8 Sv of the dense flow that is diverted around the Manihiki Plateau to the east, bypassing the Samoan Passage. This bypass flow is not confined to a channel and is therefore less likely to experience the strong mixing that is associated with hydraulic transitions. The partitioning of flux between the two branches of the deep flow could therefore be relevant to the distribution of Pacific abyssal mixing. To gain insight into the factors that control the partitioning between these two branches, we develop an abyssal and equator-proximal extension of the “island rule.” Novel features include provisions for the presence of hydraulic jumps as well as identification of an appropriate integration circuit for an abyssal layer to the east of the island. Evaluation of the corresponding circulation integral leads to a prediction of 0.4–2.4 Sv of bypass flow. The circulation integral clearly identifies dissipation and frictional drag effects within the Samoan Passage as crucial elements in partitioning the flow., This work was supported by the National Science Foundation under Grants OCE-1029268, OCE-1029483, OCE-1657264, OCE-1657870, OCE-1658027, and OCE-1657795. We thank the captain, crew, and engineers at APL/UW for their hard work and skill., 2020-06-11

Published
2019

24. Ice nucleating particles carried from below a phytoplankton bloom to the arctic atmosphere

Author

Creamean, Jessie M., Cross, Jessica N., Pickart, Robert S., McRaven, Leah T., Lin, Peigen, Pacini, Astrid, Schmale, David G., Ceniceros, Julio, Aydell, Taylor, Colombi, N., Bolger, Emily, DeMott, Paul, Hanlon, Regina, Creamean, Jessie M., Cross, Jessica N., Pickart, Robert S., McRaven, Leah T., Lin, Peigen, Pacini, Astrid, Schmale, David G., Ceniceros, Julio, Aydell, Taylor, Colombi, N., Bolger, Emily, DeMott, Paul, and Hanlon, Regina

Abstract

Author Posting. © American Geophysical Union, 2019. This article is posted here by permission of American Geophysical Union for personal use, not for redistribution. The definitive version was published in Geophysical Research Letters 46(14), (2019): 8572-8581, doi: 10.1029/2019GL083039., As Arctic temperatures rise at twice the global rate, sea ice is diminishing more quickly than models can predict. Processes that dictate Arctic cloud formation and impacts on the atmospheric energy budget are poorly understood, yet crucial for evaluating the rapidly changing Arctic. In parallel, warmer temperatures afford conditions favorable for productivity of microorganisms that can effectively serve as ice nucleating particles (INPs). Yet the sources of marine biologically derived INPs remain largely unknown due to limited observations. Here we show, for the first time, how biologically derived INPs were likely transported hundreds of kilometers from deep Bering Strait waters and upwelled to the Arctic Ocean surface to become airborne, a process dependent upon a summertime phytoplankton bloom, bacterial respiration, ocean dynamics, and wind‐driven mixing. Given projected enhancement in marine productivity, combined oceanic and atmospheric transport mechanisms may play a crucial role in provision of INPs from blooms to the Arctic atmosphere., We sincerely thank the U.S. Coast Guard and crew of the Healy for assistance with equipment installation and guidance, operation of the underway and CTD systems, and general operation of the vessel during transit and at targeted sampling stations. We would also like to thank Allan Bertram, Meng Si, Victoria Irish, and Benjamin Murray for providing INP data from their previous studies. J. M. C., R. P., P. L., L. T., and E. B. were funded by the National Oceanic and Atmospheric Administration (NOAA)’s Arctic Research Program. J. C. was supported by the NOAA Experiential Research & Training Opportunities (NERTO) program. T. A. and N. C. were supported through the NOAA Earnest F. Hollings Scholarship program. A. P. was funded by the National Science Foundation under Grant PLR‐1303617. Russel C. Schnell and Michael Spall are acknowledged for insightful discussions during data analysis and interpretation. There are no financial conflicts of interest for any author. INP data are available in the supporting information, while remaining DBO‐NCIS data presented in the manuscript are available online (at https://www2.whoi.edu/site/dboncis/)., 2020-01-15

Published
2019

26. Evolution of the freshwater coastal current at the southern tip of Greenland

Author

Lin, Peigen, Pickart, Robert S., Torres, Daniel J., Pacini, Astrid, Lin, Peigen, Pickart, Robert S., Torres, Daniel J., and Pacini, Astrid

Abstract

Author Posting. © American Meteorological Society, 2018. This article is posted here by permission of American Meteorological Society for personal use, not for redistribution. The definitive version was published in Journal of Physical Oceanography 48 (2018): 2127-2140, doi:10.1175/JPO-D-18-0035.1., Shipboard hydrographic and velocity measurements collected in summer 2014 are used to study the evolution of the freshwater coastal current in southern Greenland as it encounters Cape Farewell. The velocity structure reveals that the coastal current maintains its identity as it flows around the cape and bifurcates such that most of the flow is diverted to the outer west Greenland shelf, while a small portion remains on the inner shelf. Taking into account this inner branch, the volume transport of the coastal current is conserved, but the freshwater transport decreases on the west side of Cape Farewell. A significant amount of freshwater appears to be transported off the shelf where the outer branch flows adjacent to the shelfbreak circulation. It is argued that the offshore transposition of the coastal current is caused by the flow following the isobaths as they bend offshore because of the widening of the shelf on the west side of Cape Farewell. An analysis of the potential vorticity shows that the subsequent seaward flux of freshwater can be enhanced by instabilities of the current. This set of circumstances provides a pathway for the freshest water originating from the Arctic, as well as runoff from the Greenland ice sheet, to be fluxed into the interior Labrador Sea where it could influence convection in the basin., Funding for this project was provided by the National Science Foundation under Grant OCE-1259618., 2019-03-11

Published
2018

27. Under-ice phytoplankton blooms inhibited by spring convective mixing in refreezing leads

Author

Lowry, Kate E., Pickart, Robert S., Selz, Virginia, Mills, Matthew M., Pacini, Astrid, Lewis, Kate M., Joy-Warren, Hannah L., Nobre, Carolina, van Dijken, Gert L., Grondin, Pierre-Luc, Ferland, Joannie, Arrigo, Kevin R., Lowry, Kate E., Pickart, Robert S., Selz, Virginia, Mills, Matthew M., Pacini, Astrid, Lewis, Kate M., Joy-Warren, Hannah L., Nobre, Carolina, van Dijken, Gert L., Grondin, Pierre-Luc, Ferland, Joannie, and Arrigo, Kevin R.

Abstract

Author Posting. © American Geophysical Union, 2018. This article is posted here by permission of American Geophysical Union for personal use, not for redistribution. The definitive version was published in Journal of Geophysical Research: Oceans 123 (2018): 90–109, doi:10.1002/2016JC012575., Spring phytoplankton growth in polar marine ecosystems is limited by light availability beneath ice-covered waters, particularly early in the season prior to snowmelt and melt pond formation. Leads of open water increase light transmission to the ice-covered ocean and are sites of air-sea exchange. We explore the role of leads in controlling phytoplankton bloom dynamics within the sea ice zone of the Arctic Ocean. Data are presented from spring measurements in the Chukchi Sea during the Study of Under-ice Blooms In the Chukchi Ecosystem (SUBICE) program in May and June 2014. We observed that fully consolidated sea ice supported modest under-ice blooms, while waters beneath sea ice with leads had significantly lower phytoplankton biomass, despite high nutrient availability. Through an analysis of hydrographic and biological properties, we attribute this counterintuitive finding to springtime convective mixing in refreezing leads of open water. Our results demonstrate that waters beneath loosely consolidated sea ice (84–95% ice concentration) had weak stratification and were frequently mixed below the critical depth (the depth at which depth-integrated production balances depth-integrated respiration). These findings are supported by theoretical model calculations of under-ice light, primary production, and critical depth at varied lead fractions. The model demonstrates that under-ice blooms can form even beneath snow-covered sea ice in the absence of mixing but not in more deeply mixed waters beneath sea ice with refreezing leads. Future estimates of primary production should account for these phytoplankton dynamics in ice-covered waters., National Science Foundation (NSF) Grant Numbers: PLR-1304563 , PLR-1303617; KEL; NSF Graduate Research Fellowship Program Grant Number: DGE-0645962, 2018-07-07

Published
2018

28. Under‐Ice Phytoplankton Blooms Inhibited by Spring Convective Mixing in Refreezing Leads

Author

Lowry, Kate E., primary, Pickart, Robert S., additional, Selz, Virginia, additional, Mills, Matthew M., additional, Pacini, Astrid, additional, Lewis, Kate M., additional, Joy‐Warren, Hannah L., additional, Nobre, Carolina, additional, van Dijken, Gert L., additional, Grondin, Pierre‐Luc, additional, Ferland, Joannie, additional, and Arrigo, Kevin R., additional

Published
2018
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29. The Iceland Greenland Seas Project

Author

Renfrew, Ian A., Pickart, Robert S., Våge, Kjetil, Moore, George W.K., Bracegirdle, Thomas J., Elvidge, Andrew D., Jeansson, Emil, Lachlan-Cope, Tom A., McRaven, Leah T., Papritz, Lukas, Reuder, Joachim, Sodemann, Harald, Terpstra, Annick, Waterman, Stephanie N., Valdimarsson, Héđinn, Weiss, Alexandra, Almansi, Mattia, Bahr, Frank B., Brakstad, Ailin, Barrell, C., Brooke, Jennifer K., Brooks, Barbara J., Brooks, Ian M., Brooks, Malcolm E., Bruvik, Erik M., Duscha, C., Fer, Ilker, Hallerstig, M., Hessevik, Idar, Huang, Jie, Houghton, Leah A., Jónsson, Steingrímur, Jonassen, Marius O., Jackson, K., Kvalsund, Karsten, Kolstad, Erik W., Konstali, K., Kristiansen, Jørn, Ladkin, Russell, Lin, Peigen, MacRander, Andreas, Mitchell, A., Ólafsson, Haraldur, Pacini, Astrid, Payne, C., Palmason, B., Pérez-Hernández, María D., Peterson, Algot K., Petersen, Gudrún N., Pisareva, Maria N., Pope, James O., Seidl, Andrew, Semper, Stefanie, Sergeev, Denis E., Skjelsvik, S., Søiland, Henrik, Smith, Doug M., Spall, Michael A., Spengler, Thomas, Touzeau, Alexandra, Weng, Y., Williams, Keith D., Yang, X., and Zhou, S.

Subjects
13. Climate action, 14. Life underwater
Abstract

The Iceland Greenland Seas Project (IGP) is a coordinated atmosphere–ocean research program investigating climate processes in the source region of the densest waters of the Atlantic meridional overturning circulation. During February and March 2018, a field campaign was executed over the Iceland and southern Greenland Seas that utilized a range of observing platforms to investigate critical processes in the region, including a research vessel, a research aircraft, moorings, sea gliders, floats, and a meteorological buoy. A remarkable feature of the field campaign was the highly coordinated deployment of the observing platforms, whereby the research vessel and aircraft tracks were planned in concert to allow simultaneous sampling of the atmosphere, the ocean, and their interactions. This joint planning was supported by tailor-made convection-permitting weather forecasts and novel diagnostics from an ensemble prediction system. The scientific aims of the IGP are to characterize the atmospheric forcing and the ocean response of coupled processes; in particular, cold-air outbreaks in the vicinity of the marginal ice zone and their triggering of oceanic heat loss, and the role of freshwater in the generation of dense water masses. The campaign observed the life cycle of a long-lasting cold-air outbreak over the Iceland Sea and the development of a cold-air outbreak over the Greenland Sea. Repeated profiling revealed the immediate impact on the ocean, while a comprehensive hydrographic survey provided a rare picture of these subpolar seas in winter. A joint atmosphere–ocean approach is also being used in the analysis phase, with coupled observational analysis and coordinated numerical modeling activities underway., Bulletin of the American Meteorological Society, 100 (9), ISSN:0003-0007, ISSN:1520-0477

30. Structure and variability of the West Greenland boundary current system.

Author

Pacini, Astrid, Pickart, Robert, Bahr, Frank, Ramsey, Andree, Torres, Daniel, and Karstensen, Johannes

Subjects
*MESOSCALE eddies, *WATER masses, *FRESH water, *SEAWATER, *TERRITORIAL waters, *WATER-pipes
Abstract

The boundary current along the west coast of Greenland is the main pathway for waters circumnavigating and entering the Labrador Sea, an important site for deep convection. Until now, the year-round structure of the current system has not been investigated from an observational perspective. As part of the Overturning of the Subpolar North Atlantic Program (OSNAP), a high-resolution mooring array was maintained across the West Greenland shelf and slope near Cape Farewell, from August 2014 to August 2016. Here we use the data to investigate the structure, transport, and variability of the boundary current system. Three distinct velocity cores were present: the Deep Western Boundary Current, carrying dense overflow waters from the Nordic Seas; the Irminger Current, advecting warm and salty Atlantic-origin waters; and the West Greenland Coastal Current, transporting cold and fresh polar waters. The two-year mean transport of the full boundary current system is 33.03 ± 7.25 Sv, with no clear seasonal signal. However, the individual water mass properties show a statistically-significant seasonal cycle in hydrography and transport. In particular, there is an increase in Labrador Sea Water transport during the spring of both years, compensated by a decrease in Irminger Water and Northeast Atlantic Deep Water transport during the same period. These trends are due to changes in cross-sectional area of the water masses, not changes in the strength of the flow. In the case of the Labrador Sea Water, the seasonality can be understood as the lagged response of recently ventilated waters upstream. The boundary current is subject to energetic mesoscale variability. Both cyclonic and anticyclonic eddies progress past the array over the two-year period. We argue that the former are Denmark Strait Overflow Water cyclones that have propagated around Cape Farewell. These mesoscale features may help transport waters from the boundary current into the interior Labrador Sea, where they will influence stratification and thus modulate the strength of deep convection in the basin. [ABSTRACT FROM AUTHOR]

Published
2019

31. Abundant Cyclonic Eddies in the Deep Boundary Current Around Southern Greenland.

Author

Bower, Amy, Pacini, Astrid, Bras, Isabela le, Furey, Heather, Lozier, Susan, Pickart, Robert, Ramsey, Andree, Straneo, Fiamma, and Zou, Sijia

Subjects
*EDDIES, *MESOSCALE eddies, *MERIDIONAL overturning circulation, *CONTINENTAL slopes, *LEG, *WATER masses
Abstract

The deep boundary current of the subpolar North Atlantic transports cold, dense North Atlantic Deep Water (NADW) equatorward, representing the lower limb of the Atlantic Meridional Overturning circulation (AMOC) at these latitudes. This current is typically illustrated as a continuous ribbon that cyclonically follows the boundaries of the three subpolar basins (Iceland, Irminger, Labrador), demonstrating the strong influence of topography on the pathways of these deep waters. As part of the Overturning in the Subpolar North Atlantic Program (OSNAP), about 120 acoustically tracked (RAFOS) floats were released between 2014 and 2017 at various locations along the deep boundary current path (at depths between 1800 and 2800 m) to determine where and why this topographic constraint breaks down, allowing boundary-interior exchange and water mass transformation. Anticipating that one such location might be the southern tip of Greenland due to the sharp curvature of the isobaths associated with the Eirik Ridge, a large number of floats were released on the OSNAP line just upstream of the ridge. Contrary to expectations, A relatively small number of floats separated from the continental slope at this location, but surprisingly, a significant number of floats exhibited cusping or looping behavior consistent with being trapped in coherent cyclonic eddies embedded in the boundary current. These eddies are also evident in the velocity and T/S measurements from OSNAP moored arrays just upstream and downstream of the ridge, indicating that at least some of these eddies are able to round the ridge and enter the Labrador Basin. The physical and kinematic properties of the eddies observed around southern Greenland are similar to the deep cyclonic eddies observed upstream in the deep boundary current, which are thought to form due to vortex stretching along the path of the descending Denmark Strait Overflow, suggesting that some of these upstream eddies are long-lived and remain intact all the way to the Labrador Basin. Using both the OSNAP moored and float observations, we will describe the velocity and hydrographic structure of the eddies around southern Greenland, which are numerous. On the one hand, NADW trapped in eddy cores will be isolated from lateral mixing with surrounding water, but the rotational velocity associated with the eddies may enhance stirring and mixing around their perimeters. [ABSTRACT FROM AUTHOR]

Published
2019

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