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Causes for Atlantic Freshwater Content Variability in the GECCO3 Ocean Synthesis (2022)

Liu, Xin ; Köhl, Armin ; Stammer, Detlef ; [et al.]

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Publication Date: 2024-01-26

Description: Regional freshwater content (FWC) changes are studied over the period 1961–2018 using the GECCO3 ocean synthesis. In four dynamically distinct regions of the Atlantic, the study identifies causes for FWC variability with a focus on interannual and decadal time‐scale changes. Results show that in each region, it is a combination of the surface freshwater flux and the net freshwater transport across the region's boundaries that act jointly in changing the respective FWC. Surface flux mainly contributes to the FWC variability on multi‐decadal time scales. The impact of surface flux also increases toward the tropics. On shorter time scales, it is especially horizontal transport fluctuations, leading to FWC changes in mid and high latitudes. Going from north to the south, the transport across a single meridional boundary becomes less correlated with the FWC changes but the net transport across both boundaries plays an increasingly important role. Moreover, the subpolar box is mainly gyre driven, which differs from the other two, essentially overturning driven, North Atlantic boxes. In the tropical Atlantic, the shallow overturning cell and the deep overturning contribute about equal amounts to the freshwater variations.

Description: Plain Language Summary: Causes for freshwater content (FWC) variability in the Atlantic Ocean are analyzed for four study areas over the period 1961–2018 based on a model simulation (GECCO3 ocean synthesis). Targeting relatively long time scales, interannual, decadal to multi‐decadal FWC changes are separated into the contributions from variations of the freshwater input/output through the ocean surface and from freshwater transport (FWT) variations related to the ocean circulation changes. Surface freshwater flux is more influential on multi‐decadal time scales, and its impact increases toward the tropics. On shorter time scales, the oceanic FWT across the boundaries of the region dominates the FWC changes in mid and high latitudes. The transport variability in the subpolar region is mainly driven by the horizontal circulation, while transports resulting from vertical salinity differences are more important at lower latitudes. Moreover, in the tropics transports related to shallow salinity differences are not negligible on interannual time scales.

Description: Key Points: The net freshwater transport across the meridional boundaries dominates the freshwater content variations in mid and high latitudes. The importance of surface freshwater flux variations increases toward the tropics and on multi‐decadal time scales. Subpolar changes are mainly gyre driven, while overturning and especially the shallow overturning cells contribute more at lower latitudes.

Description: Deutsche Forschungsgemeinschaft http://dx.doi.org/10.13039/501100001659

Description: https://icdc.cen.uni-hamburg.de/en/gecco3.html

Description: http://www.metoffice.gov.uk/hadobs/en4/download-en4-2-2.html

Description: https://www.cen.uni-hamburg.de/en/icdc/data/atmosphere/hoaps.html

Keywords: ddc:551.46 ; Atlantic Ocean ; freshwater content (FWC) ; regional changes ; GECCO3

Language: English

Type: doc-type:article

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Growth and Decay of Northwestern Tropical Atlantic Barrier Layers (2021)

Saha, Aurpita ; Serra, Nuno ; Stammer, Detlef

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Publication Date: 2021-07-21

Description: The growth and decay mechanisms of barrier layers in the northwestern tropical Atlantic are studied by investigating small‐scale processes embedded in the regional circulation of the tropical Atlantic using output from an eddy‐resolving numerical simulation at 4 km resolution forced by an atmospheric reanalysis. The simulation reproduces well the temporal and spatial patterns of barrier layer thickness (BLT) estimated with Argo and CTD in situ profiles. As seen from an analysis of the salinity and temperature vertical gradient balances, localized large barrier layers form inside North Brazil Current rings during late‐June to July because of a thickening of the isothermal layer in the rings due to horizontal temperature advection, stretching of isotherms and tilting of temperature fronts. These barrier layers decay when the isothermal layer reduces again due to the above mechanisms. Further to the north, along the North Equatorial Current, the seasonal variability of BLT is highly pronounced. Thick winter (January to early March) barrier layers locally grow as the base of the mixed layer shoals mainly due to a tilting of the salinity fronts and partly due to stretching of the isohalines, horizontal salt advection and vertical turbulent mixing. The short‐term barrier layers in this case decay due to a deepening of the mixed layer, whereas they get completely eroded in spring by a shoaling of the isothermal layer due to surface temperature stratification. This work highlights that barrier layers are localized phenomena at times growing solely due to ocean dynamics, without a surface freshwater influx.

Description: Plain Language Summary: Oceanic barrier layers exist in regions where salinity is more dominant than temperature in determining upper ocean density. Those layers lie between the bases of a constant‐density layer and a constant‐temperature layer. Barrier layers prevent vertical exchange of energy and mass between the near‐surface and the deep ocean, thus influencing air‐sea interaction. In the western tropical Atlantic, a warmer sea surface due to the presence of barrier layers can fuel hurricanes. Freshwater from the Amazon River and rainfall facilitate the growth of barrier layers, but the dynamics of their evolution are unclear. In this work, we identify/quantify the growth and decay mechanisms of barrier layers using a 4 km resolution simulation. Barrier layers grow/decay inside North Brazil Current eddies in summer because of deepening/shoaling of the constant‐temperature layer inside the eddies due to horizontal heat transport. Further north, barrier layers grow in winter as the constant‐density layer shoals mainly due to northwestward surface freshwater flow and equatorward subsurface salty water flow. Those barrier layers decay when the constant‐density layer deepens, whereas are destroyed when the constant‐temperature layer shoals in spring due to surface heating. These novel results improve the knowledge on barrier layers and help representing them in climate models.

Description: Key Points: The North Brazil and North Equatorial Currents are two regions with quasi‐permanent barrier layers in the northwestern tropical Atlantic Large barrier layer thickness (BLT) within the rings occurs during June‐July due to a thickening of the isothermal layer within the eddies Large winter BLT in North Equatorial Current is due to tilting of salinity fronts, stretching of isohalines, advection and turbulent mixing

Description: Deutsche Forschungsgemeinschaft (DFG) http://dx.doi.org/10.13039/501100001659

Keywords: 551.46 ; northwestern tropical Atlantic ; barrier layers

Type: article

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Arctic ocean–sea ice reanalysis for the period 2007–2016 using the adjoint method (2021)

Lyu, Guokun ; Koehl, Armin ; Serra, Nuno ; [et al.]

John Wiley & Sons, Ltd | Chichester, UK

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Publication Date: 2021-07-20

Description: We present an Arctic ocean–sea ice reanalysis covering the period 2007–2016 based on the adjoint approach of the Estimating the Circulation and Climate of the Ocean (ECCO) consortium. The spatiotemporal variation of Arctic sea surface temperature (SST), sea ice concentration (SIC), and sea ice thickness (SIT) is substantially improved after the assimilation of ocean and sea ice observations. By assimilating additional World Ocean Atlas 2018 (WOA18) hydrographic data, the freshwater content of the Canadian Basin becomes closer to the observations and translates into changes of the ocean circulation and of transports through the Fram and Davis straits. This new reanalysis compares well with previous filter‐based (TOPAZ4) and nudging‐based (PIOMAS) reanalyses regarding SIC and SST. Benefiting from using the adjoint of the sea ice model, our reanalysis is superior to the ECCOv4r4 product considering sea ice parameters. However, the mean state and variability of the freshwater content and the transport properties of our reanalysis remain different from TOPAZ4 and ECCOv4r4, likely because of a lack of hydrographic observations.

Description: Arctic sea ice has declined rapidly and reached a record minimum in September, 2012. Arctic ocean–sea ice reanalyses are invaluable sources for understanding the Arctic sea ice changes. We produce an Arctic ocean–sea ice reanalysis of the years 2007–2016 using the adjoint method. The reanalysis is dynamically consistent without introducing unphysical mass and energy discontinuities as in filter‐based data assimilation methods.

Keywords: 551 ; adjoint method ; data assimilation ; ocean–sea ice reanalysis

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