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Physical oceanography from 30 helicopter-borne CTDs during POLARSTERN cruise ANT-XXII/2 (ISPOL) (2008)

Absy, Joao Marcelo ; Schröder, Michael ; Muench, Robin D ; [et al.]

PANGAEA

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Publication Date: 2023-03-16

Keywords: ANT-XXII/2; ANT-XXII/2_003-1; ANT-XXII/2_004-1; ANT-XXII/2_005-1; ANT-XXII/2_006-1; ANT-XXII/2_007-1; ANT-XXII/2_007-22; ANT-XXII/2_008-1; ANT-XXII/2_008-22; ANT-XXII/2_009-1; ANT-XXII/2_009-22; ANT-XXII/2_010-1; ANT-XXII/2_011-1; ANT-XXII/2_012-1; ANT-XXII/2_013-1; ANT-XXII/2_014-1; ANT-XXII/2_015-1; ANT-XXII/2_016-1; ANT-XXII/2_017-1; ANT-XXII/2_018-1; ANT-XXII/2_019-1; ANT-XXII/2_020-1; ANT-XXII/2_021-1; ANT-XXII/2_022-1; ANT-XXII/2_066-22; ANT-XXII/2_139-22; ANT-XXII/2_140-22; ANT-XXII/2_142-22; ANT-XXII/2_143-22; ANT-XXII/2_144-22; ANT-XXII/2_146-22; AWI_PhyOce; Calculated; Conductivity; CTD, SEA-BIRD SBE 19, SN 2715, modified for continuous data acquisition; CTD from ice float; CTDIF; Date/Time of event; Density, sigma-theta (0); DEPTH, water; Elevation of event; Event label; Latitude of event; Longitude of event; Physical Oceanography @ AWI; Polarstern; Pressure, water; PS67 ISPOL; Salinity; Temperature, water; Temperature, water, potential; Weddell Sea

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Format: text/tab-separated-values, 167622 data points

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25 Jahre Alfred-Wegener-Institut für Polar- und Meeresforschung (poster) (2005)

Abele, Doris ; Arntz, Wolf E ; Beninga, Ingo ; [et al.]

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In: Alfred Wegener Institute, Helmholtz Centre for Polar and Marine Research, Bremerhaven

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Publication Date: 2023-09-01

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Format: application/zip, 11.5 MBytes

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(Table 1) Iceberg characteristics and start and end date and location of iceberg buoys in the Weddell Sea (2006)

Schodlok, Michael P ; Hellmer, Hartmut H ; Rohardt, Gerd ; [et al.]

PANGAEA

In: Supplement to: Schodlok, Michael P; Hellmer, Hartmut H; Rohardt, Gerd; Fahrbach, Eberhard (2006): Weddell Sea iceberg drift: Five years of observations. Journal of Geophysical Research, 111(C6), https://doi.org/10.1029/2004JC002661

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Publication Date: 2023-10-28

Description: The drift of 52 icebergs tagged with GPS buoys in the Weddell Sea since 1999 has been investigated with respect to prevalent drift tracks, sea ice/iceberg interaction, and freshwater fluxes. Buoys were deployed on small- to medium-sized icebergs (edge lengths 〈= 5 km) in the southwestern and eastern Weddell Sea. The basin-scale iceberg drift of this size class was established. In the western Weddell Sea, icebergs followed a northward course with little deviation and mean daily drift rates up to 9.5 ± 7.3 km/d. To the west of 40°W the drift of iceberg and sea ice was coherent. In the highly consolidated perennial sea ice cover of 95% the sea ice exerted a steering influence on the icebergs and was thus responsible for the coherence of the drift tracks. The northward drift of buoys to the east of 40°W was interrupted by large deviations due to the passage of low-pressure systems. Mean daily drift rates in this area were 11.5 ± 7.2 km/d. A lower threshold of 86% sea ice concentration for coherent sea ice/iceberg movement was determined by examining the sea ice concentration derived from Special Sensor Microwave Imager (SSM/I) and Advanced Microwave Scanning Radiometer for EOS (AMSR-E) satellite data. The length scale of coherent movement was estimated to be at least 200 km, about half the value found for the Arctic Ocean but twice as large as previously suggested. The freshwater fluxes estimated from three iceberg export scenarios deduced from the iceberg drift pattern were highly variable. Assuming a transit time in the Weddell Sea of 1 year, the iceberg meltwater input of 31 Gt which is about a third of the basal meltwater input from the Filchner Ronne Ice Shelf but spreads across the entire Weddell Sea. Iceberg meltwater export of 14.2 × 103 m3 s-1, if all icebergs are exported, is in the lower range of freshwater export by sea ice.

Keywords: AWI_SeaIce; Date/time end; Date/time start; Freeboard; Identification; LATITUDE; Latitude 2; Length; LONGITUDE; Longitude 2; ORDINAL NUMBER; Priority Programme 1158 Antarctic Research with Comparable Investigations in Arctic Sea Ice Areas; Sea Ice Physics @ AWI; SPP1158; Width

Type: Dataset

Format: text/tab-separated-values, 422 data points

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Chlorofluorocarbons, helium, and neon measured on water bottle samples during POLARSTERN cruise ANT-XXII/2 (ISPOL) (2008)

Huhn, Oliver ; Hellmer, Hartmut H ; Rhein, Monika ; [et al.]

PANGAEA

In: Supplement to: Huhn, Oliver; Hellmer, Hartmut H; Rhein, Monika; Rodehacke, Christian; Roether, Wolfgang; Schodlok, Michael P; Schröder, Michael (2008): Evidence of deep- and bottom-water formation in the western Weddell Sea. Deep Sea Research Part II: Topical Studies in Oceanography, 55(8-9), 1098-1116, https://doi.org/10.1016/j.dsr2.2007.12.015

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Publication Date: 2023-10-28

Description: During Ice Station POLarstern (ISPOL; R.V. Polarstern cruise ANT XXII/2, November 2004-January 2005), hydrographic and tracer observations were obtained in the western Weddell Sea while drifting closely in front of the Larsen Ice Shelf. These observations indicate recently formed Weddell Sea Bottom Water, which contains significant contributions of glacial melt water in its upper part, and High-Salinity Shelf Water in its lower layer. The formation of this bottom water cannot be related to the known sources in the south, the Filchner-Ronne Ice Shelf. We show that this bottom water is formed in the western Weddell Sea, most likely in interaction with the Larsen C Ice Shelf. By applying an Optimum Multiparameter Analysis (OMP) using temperature, salinity, and noble gas observations (helium isotopes and neon), we obtained mean glacial melt-water fractions of about 0.1% in the bottom water. On sections across the Weddell Gyre farther north, melt-water fractions are still on the order of 0.04%. Using chlorofluorocarbons (CFCs) as age tracers, we deduced a mean transit time between the western source and the bottom water found on the slope toward the north (9±3 years). This transit time is larger and the inferred transport rate is small in comparison to previous findings. But accounting for a loss of the initially formed bottom water volume due to mixing and renewal of Weddell Sea Deep Water, a formation rate of 1.1±0.5 Sv in the western Weddell Sea is plausible. This implies a basal melt rate of 35±19 Gt/year or 0.35±0.19 m/year at the Larsen Ice Shelf. This bottom water is shallow enough that it could leave the Weddell Basin through the gaps in the South Scotia Ridge to supply Antarctic Bottom Water. These findings emphasize the role of the western Weddell Sea in deep- and bottom-water formation, particularly in view of changing environmental conditions due to climate variability, which might induce enhanced melting or even decay of ice shelves.

Keywords: ANT-XXII/2; ANT-XXII/2_003-1; ANT-XXII/2_005-1; ANT-XXII/2_006-1; ANT-XXII/2_007-1; ANT-XXII/2_008-1; ANT-XXII/2_009-1; ANT-XXII/2_010-1; ANT-XXII/2_011-1; ANT-XXII/2_012-1; ANT-XXII/2_013-1; ANT-XXII/2_014-1; ANT-XXII/2_015-1; ANT-XXII/2_017-1; ANT-XXII/2_018-1; ANT-XXII/2_019-1; ANT-XXII/2_020-1; ANT-XXII/2_022-1; CTD/Rosette; CTD from ice float; CTDIF; CTD-RO; ICE; Ice station; Polarstern; Priority Programme 1158 Antarctic Research with Comparable Investigations in Arctic Sea Ice Areas; PS67/005-1; PS67/006-1; PS67/006-100; PS67/006-102; PS67/006-103; PS67/006-108; PS67/006-109; PS67/006-11; PS67/006-110; PS67/006-111; PS67/006-113; PS67/006-115; PS67/006-118; PS67/006-12; PS67/006-120; PS67/006-123; PS67/006-126; PS67/006-128; PS67/006-13; PS67/006-130; PS67/006-131; PS67/006-134; PS67/006-135; PS67/006-139; PS67/006-140; PS67/006-142; PS67/006-144; PS67/006-146; PS67/006-15; PS67/006-18; PS67/006-19; PS67/006-2; PS67/006-21; PS67/006-22; PS67/006-23; PS67/006-25; PS67/006-27; PS67/006-30; PS67/006-32; PS67/006-35; PS67/006-38; PS67/006-4; PS67/006-40; PS67/006-41; PS67/006-43; PS67/006-45; PS67/006-47; PS67/006-48; PS67/006-51; PS67/006-53; PS67/006-57; PS67/006-59; PS67/006-61; PS67/006-63; PS67/006-65; PS67/006-66; PS67/006-68; PS67/006-7; PS67/006-70; PS67/006-73; PS67/006-74; PS67/006-76; PS67/006-78; PS67/006-79; PS67/006-82; PS67/006-84; PS67/006-87; PS67/006-89; PS67/006-9; PS67/006-92; PS67/006-94; PS67/006-96; PS67/006-98; PS67/006-99; PS67/007-1; PS67/008-1; PS67/009-1; PS67/011-1; PS67/011-2; PS67/011-3; PS67 ISPOL; Scotia Sea, southwest Atlantic; SPP1158; Weddell Sea

Type: Dataset

Format: application/zip, 2 datasets

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Physical oceanography measured on water bottle samples during POLARSTERN cruise ANT-XXII/2 (ISPOL) (2008)

Absy, Joao Marcelo ; Schröder, Michael ; Muench, Robin D ; [et al.]

PANGAEA

In: Alfred Wegener Institute, Helmholtz Centre for Polar and Marine Research, Bremerhaven

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Publication Date: 2024-02-27

Keywords: ANT-XXII/2; AWI_PhyOce; Bottle number; Calculated; Calculated from pressure, temperature, and conductivity; Conductivity; CTD, Sea-Bird SBE 911plus; CTD/Rosette; CTD-RO; Date/Time of event; Density, sigma-theta (0); DEPTH, water; Elevation of event; Event label; Latitude of event; Longitude of event; Physical Oceanography @ AWI; Polarstern; Pressure, water; PS67/005-1; PS67/006-100; PS67/006-102; PS67/006-103; PS67/006-108; PS67/006-109; PS67/006-11; PS67/006-110; PS67/006-111; PS67/006-113; PS67/006-115; PS67/006-118; PS67/006-12; PS67/006-120; PS67/006-123; PS67/006-126; PS67/006-128; PS67/006-13; PS67/006-130; PS67/006-131; PS67/006-134; PS67/006-135; PS67/006-139; PS67/006-140; PS67/006-142; PS67/006-144; PS67/006-146; PS67/006-15; PS67/006-18; PS67/006-19; PS67/006-2; PS67/006-21; PS67/006-22; PS67/006-23; PS67/006-25; PS67/006-27; PS67/006-30; PS67/006-32; PS67/006-35; PS67/006-38; PS67/006-4; PS67/006-40; PS67/006-41; PS67/006-43; PS67/006-45; PS67/006-47; PS67/006-48; PS67/006-51; PS67/006-53; PS67/006-57; PS67/006-59; PS67/006-61; PS67/006-63; PS67/006-65; PS67/006-66; PS67/006-68; PS67/006-7; PS67/006-70; PS67/006-73; PS67/006-74; PS67/006-76; PS67/006-78; PS67/006-79; PS67/006-82; PS67/006-84; PS67/006-87; PS67/006-89; PS67/006-9; PS67/006-92; PS67/006-94; PS67/006-96; PS67/006-98; PS67/006-99; PS67/007-1; PS67/008-1; PS67/009-1; PS67/011-1; PS67/011-2; PS67/011-3; PS67 ISPOL; Salinity; Scotia Sea, southwest Atlantic; Temperature, water; Temperature, water, potential; Weddell Sea

Type: Dataset

Format: text/tab-separated-values, 10094 data points

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Helium and neon measured on helicopter CTD samples during POLARSTERN cruise ANT-XXII/2 (ISPOL) (2008)

Huhn, Oliver ; Hellmer, Hartmut H ; Rhein, Monika ; [et al.]

PANGAEA

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Publication Date: 2024-05-23

Keywords: ANT-XXII/2; ANT-XXII/2_003-1; ANT-XXII/2_005-1; ANT-XXII/2_006-1; ANT-XXII/2_007-1; ANT-XXII/2_008-1; ANT-XXII/2_009-1; ANT-XXII/2_010-1; ANT-XXII/2_011-1; ANT-XXII/2_012-1; ANT-XXII/2_013-1; ANT-XXII/2_014-1; ANT-XXII/2_015-1; ANT-XXII/2_017-1; ANT-XXII/2_018-1; ANT-XXII/2_019-1; ANT-XXII/2_020-1; ANT-XXII/2_022-1; CTD from ice float; CTDIF; Date/Time of event; DEPTH, water; Elevation of event; Event label; Helium; Isotope ratio mass spectrometry; Latitude of event; Longitude of event; Neon; Polarstern; PS67 ISPOL; Weddell Sea; δ Helium-3

Type: Dataset

Format: text/tab-separated-values, 51 data points

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Chlorofluorocarbons, helium, and neon measured on water bottle samples during POLARSTERN cruise ANT-XXII/2 (ISPOL) (2008)

Huhn, Oliver ; Hellmer, Hartmut H ; Rhein, Monika ; [et al.]

PANGAEA

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Publication Date: 2024-05-23

Keywords: ANT-XXII/2; Bottle number; CTD/Rosette; CTD-RO; Date/Time of event; DEPTH, water; Elevation of event; Event label; Freon-11 (trichorofluoromethane); Freon-12 (dichlorodifluoromethane); Gas chromatography; Helium; ICE; Ice station; Isotope ratio mass spectrometry; Latitude of event; Longitude of event; Neon; Polarstern; PS67/005-1; PS67/006-1; PS67/006-103; PS67/006-108; PS67/006-115; PS67/006-120; PS67/006-126; PS67/006-13; PS67/006-131; PS67/006-135; PS67/006-139; PS67/006-142; PS67/006-25; PS67/006-32; PS67/006-38; PS67/006-4; PS67/006-43; PS67/006-48; PS67/006-53; PS67/006-61; PS67/006-65; PS67/006-66; PS67/006-70; PS67/006-74; PS67/006-79; PS67/006-84; PS67/006-89; PS67/006-94; PS67/006-99; PS67/007-1; PS67/008-1; PS67/009-1; PS67/011-3; PS67 ISPOL; Scotia Sea, southwest Atlantic; Weddell Sea; δ Helium-3

Type: Dataset

Format: text/tab-separated-values, 2374 data points

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Exceptionally warm and prolonged flow of warm deep water toward the Filchner-Ronne Ice Shelf in 2017 (2020)

Ryan, Svenja ; Hellmer, Hartmut H. ; Janout, Markus A. ; [et al.]

Wiley

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Publication Date: 2022-10-26

Description: © The Author(s), 2020. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Ryan, S., Hellmer, H. H., Janout, M., Darelius, E., Vignes, L., & Schroeder, M. Exceptionally warm and prolonged flow of warm deep water toward the Filchner-Ronne Ice Shelf in 2017. Geophysical Research Letters, 47(13),(2020): e2020GL088119, doi:10.1029/2020GL088119.

Description: The Filchner‐Ronne Ice Shelf, fringing the southern Weddell Sea, is Antarctica's second largest ice shelf. At present, basal melt rates are low due to active dense water formation; however, model projections suggest a drastic increase in the future due to enhanced inflow of open‐ocean warm water. Mooring observations from 2014 to 2016 along the eastern flank of the Filchner Trough (76°S) revealed a distinct seasonal cycle with inflow if Warm Deep Water during summer and autumn. Here we present extended time series showing an exceptionally warm and long inflow in 2017, with maximum temperatures exceeding 0.5°C. Warm temperatures persisted throughout winter, associated with a fresh anomaly, which lead to a change in stratification over the shelf, favoring an earlier inflow in the following summer. We suggest that the fresh anomaly developed upstream after anomalous summer sea ice melting and contributed to a shoaling of the shelf break thermocline.

Description: The authors would like to express their gratitude to the officers and crews of RV Polarstern (cruises PS92 [Grant AWI_PS82_02], PS96 [Grant AWI_PS96_01], and PS111 [Grant AWI_PS111_01]), RRS Ernest Shackleton (Cruise ES060), and RSS James Clark Ross (Cruise JR16004) for their efficient assistance. E. D. received funding from the project TOBACO (267660), POLARPROG, Norges Forskningsrd.

Keywords: Ocean-ice shelf interaction ; Weddell Sea ; Warm inflow ; Antarctic Slope Front ; Filchner-Ronne Ice Shelf

Repository Name: Woods Hole Open Access Server

Type: Article

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Tipping of the Filchner-Ronne and other Antarctic ice shelf cavities (2022)

Haid, Verena ; Timmermann, Ralph ; Hellmer, Hartmut H.

EGU General Assembly 2022

In: EPIC3EGU General Assembly 2022, Vienna, 2022Vienna, EGU General Assembly 2022

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Publication Date: 2022-10-27

Description: Tipping of an ice shelf cavity from a cold to a warm state happens when a sustained inflow of warm Circumpolar Deep Water (CDW) or a modified variant of it replaces High Salinity Shelf Water (HSSW) and Ice Shelf Water (ISW) in a cold-water cavity. HSSW and ISW with temperatures close to or even below the surface freezing point provide little heat for melting glacial ice. CDW derivatives, however, can cause a substantial multiplication of the ice shelf basal melt rates. The increased melt water release may trigger a positive feedback loop that stabilizes the warm state. Therefore, if the outside circumstances turned back to previous conditions, a reversal from warm to cold would not occur under the same conditions as the switch from cold to warm. A warm tipping has been found possible for the Filchner-Ronne Ice Shelf (FRIS) cavity in previous studies. In the framework of the EU project TiPACCs, we now reinforce our focus on the conditions which can cause a tipping for the Filchner Ronne and other Antarctic ice shelf cavities. We conducted a series of FESOM-1.4 simulations with different manipulations of the atmospheric forcing variables in order to analyse the common factors of tipping events, opposed to more stable results. We found that for the Filchner Trough region in a warming world, the crucial balance is between the different rates of warming and freshening of (a) the continental shelf waters in front of the ice shelf and (b) the waters transported with the slope current. While other studies identified an uplift of the pycnocline at the continental shelf break as a necessary condition for warm onshore flow, we deem a tipping more likely to hinge on the density loss of the shelf waters. When density on the continental shelf decreases more rapidly than in the slope current at sill depth, the ice shelf cavity is prone to tip. Reversibility of the tipping is possible within three decades under ERA Interim atmospheric forcing (1979-2017), but our study also confirms that hysteresis effects can cause a bistability of warm and cold state in the FRIS cavity under the 20th century HadCM3 forcing.

Repository Name: EPIC Alfred Wegener Institut

Type: Conference , NonPeerReviewed

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FRIS revisited in 2018: on the circulation and water masses at the Filchner and Ronne Ice Shelves in the Southern Weddell Sea (2021)

Janout, Markus A. ; Hellmer, Hartmut H. ; Hattermann, Tore ; [et al.]

American Geophysical Union

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Publication Date: 2022-10-26

Description: © The Author(s), 2021. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Janout, M. A., Hellmer, H. H., Hattermann, T., Huhn, O., Sueltenfuss, J., Osterhus, S., Stulic, L., Ryan, S., Schroeder, M., & Kanzow, T. FRIS revisited in 2018: on the circulation and water masses at the Filchner and Ronne Ice Shelves in the Southern Weddell Sea. Journal of Geophysical Research: Oceans, 126(6), (2021): e2021JC017269, https://doi.org/10.1029/2021JC017269.

Description: The Filchner-Ronne Ice Shelf (FRIS) is characterized by moderate basal melt rates due to the near-freezing waters that dominate the wide southern Weddell Sea continental shelf. We revisited the region in austral summer 2018 with detailed hydrographic and noble gas surveys along FRIS. The FRIS front was characterized by High Salinity Shelf Water (HSSW) in Ronne Depression, Ice Shelf Water (ISW) on its eastern flank, and an inflow of modified Warm Deep Water (mWDW) entering through Central Trough. Filchner Trough was dominated by Ronne HSSW-sourced ISW, likely forced by a recently intensified circulation beneath FRIS due to enhanced sea ice production in the Ronne polynya since 2015. Glacial meltwater fractions and tracer-based water mass dating indicate two separate ISW outflow cores, one hugging the Berkner slope after a two-year travel time, and the other located in the central Filchner Trough following a ∼six year-long transit through the FRIS cavity. Historical measurements indicate the presence of two distinct modes, in which water masses in Filchner Trough were dominated by either Ronne HSSW-derived ISW (Ronne-mode) or more locally derived Berkner-HSSW (Berkner-mode). While the dominance of these modes has alternated on interannual time scales, ocean densities in Filchner Trough have remained remarkably stable since the first surveys in 1980. Indeed, geostrophic velocities indicated outflowing ISW-cores along the trough's western flank and onto Berkner Bank, which suggests that Ronne-ISW preconditions Berkner-HSSW production. The negligible density difference between Berkner- and Ronne-mode waters indicates that each contributes cold dense shelf waters to protect FRIS against inflowing mWDW.

Description: This study used samples and data provided by the Alfred Wegener Institute Helmholtz-Center for Polar- and Marine Research in Bremerhaven (Grant No. AWI-PS111_01). The authors thank Captain Schwarze and the crew of RV Polarstern for a very successful expedition. We acknowledge support from the EU Horizon 2020 grants 820575 (HHH, SØ) and 821001 (TK, SØ).

Keywords: Ocean circulation ; Ocean-ice shelf interaction ; Water masses ; Weddell Sea ; Filcher and Ronne shelves

Repository Name: Woods Hole Open Access Server

Type: Article

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