Interannual Variation of Modified Circumpolar Deep Water in the Dotson‐Getz Trough, West Antarctica

Kim, Tae‐Wan; Yang, Hee Won; Dutrieux, Pierre; Wåhlin, Anna; Jenkins, Adrian; Kim, Yeong Gi; Ha, Ho Kyung; Kim, Chang-Sin; Cho, Kyoung‐Ho; Park, Taewook; Park, Jisoo; Lee, Sanghoon; Cho, Y. K.

doi:10.1029/2021jc017491

Cited by 26 publications

(33 citation statements)

References 44 publications

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“…St-Laurent et al (2015) and Webber et al (2017) emphasized the influence of local sea ice formation and air-sea heat fluxes on water temperatures over the Amundsen Sea continental shelf. Additionally, Kim et al (2021) found much larger variability in mCDW properties in the Dotson Trough close to the coast, as compared to at the shelf break. Warm and cold regimes in the Amundsen Sea have been identified using observations (e.g., Jenkins et al, 2018;Webber et al, 2017) and models (e.g., Dotto et al, 2019;Dutrieux et al, 2014;Nakayama et al, 2018).…”

mentioning

confidence: 78%

“…The results are similar if the average is calculated using the water column below the temperature maximum, so the latter is not presented here. We also tested using the mCDW layer thickness which has been demonstrated to be the main driver in heat content variability on the Amundsen Sea continental shelf (e.g., Jenkins et al., 2018 ; Kim et al., 2021 ; Thoma et al., 2008 ), but this approach gave similar results to the average temperature below 300 m, so is not presented here. In general, GLORYS has small regional temperature biases (<0.4 °C) in temperature with respect to the Worlds Ocean Atlas climatology 2013 and in situ data (Drévillon et al., 2021 ).…”

Section: The Glorys12v1 Reanalysis and Climatologymentioning

confidence: 99%

“…Additionally, Kim et al. ( 2021 ) found much larger variability in mCDW properties in the Dotson Trough close to the coast, as compared to at the shelf break. Warm and cold regimes in the Amundsen Sea have been identified using observations (e.g., Jenkins et al., 2018 ; Webber et al., 2017 ) and models (e.g., Dotto et al., 2019 ; Dutrieux et al., 2014 ; Nakayama et al., 2018 ).…”

Section: Introductionmentioning

confidence: 98%

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Wind‐Induced Variability of Warm Water on the Southern Bellingshausen Sea Continental Shelf

et al. 2022

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mentioning

confidence: 78%

Section: The Glorys12v1 Reanalysis and Climatologymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 98%

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Wind‐Induced Variability of Warm Water on the Southern Bellingshausen Sea Continental Shelf

et al. 2022

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“…Ice shelf melt rates throughout West Antarctica vary over decadal ( 12 , 13 ), interannual ( 14 ), and seasonal ( 15 ) time scales. Modifications to the surface wind stress over the continental shelf break and their influence over heat transport onto the continental shelf have been cited as a key mechanism to explain variable melt rates at individual ice shelves, particularly in the Amundsen Sea ( 11 , 12 , 16 ). Numerical simulations indicate that the thickness of CDW, particularly in the eastern sector of the Amundsen Sea, responds on short, seasonal time scales to wind fluctuations ( 17 , 18 ).…”

Section: Introductionmentioning

confidence: 99%

Antarctic Peninsula warming triggers enhanced basal melt rates throughout West Antarctica

et al. 2022

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The observed acceleration of ice shelf basal melt rates throughout West Antarctica could destabilize continental ice sheets and markedly increase global sea level. Explanations for decadal-scale melt intensification have focused on processes local to shelf seas surrounding the ice shelves. A suite of process-based model experiments, guided by CMIP6 forcing scenarios, show that freshwater forcing from the Antarctic Peninsula, propagated between marginal seas by a coastal boundary current, causes enhanced melting throughout West Antarctica. The freshwater anomaly stratifies the ocean in front of the ice shelves and modifies vertical and lateral heat fluxes, enhancing heat transport into ice shelf cavities and increasing basal melt. Increased glacial runoff at the Antarctic Peninsula, one of the first signatures of a warming climate in Antarctica, emerges as a key trigger for increased ice shelf melt rates in the Amundsen and Bellingshausen Seas.

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“…The ASL is a crucial driver of modern West Antarctic climate variability and controls the meridional winds directed toward West Antarctica (Hosking et al., 2013; Turner et al., 2013; Wang et al., 2020). Furthermore, variability of the ASL may play a role in accelerating glacial ice loss (Hosking et al., 2016), due to its influence on the heat budget (Dotto et al., 2020), the cavity circulation (Hattermann et al., 2021), the upwelling of warm CDW in polynyas (Kim et al., 2021), and the import of CDW beneath the ice shelves (Holland et al., 2019). All those processes could act to induce ocean‐forced ice‐sheet instability in this region.…”

Section: Discussionmentioning

confidence: 99%

Ocean‐Forced Instability of the West Antarctic Ice Sheet Since the Mid‐Pleistocene

Wang

Tang

Wilson

et al. 2022

Geochem Geophys Geosyst

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Evidence on West Antarctic Ice Sheet (WAIS) instability through Pleistocene glacial/interglacial cycles can provide fundamental constraints on interactions between the climate system and cryosphere. To explore such ice sheet‐ocean‐climate processes on orbital timescales over the last ∼770 ka, we provide continuous records of iceberg‐rafted debris (IRD) content and clay mineralogy, supported by detrital Sr‐Nd isotopes from the pronounced IRD peaks, in gravity core ANT34/A2‐10 from the Amundsen abyssal plain. The IRD record reveals interglacial WAIS instability since ∼770 ka, while comparison to the clay mineralogy record and published records of regional oceanic and atmospheric forcing suggests a temporal link with a strengthened Antarctic Circumpolar Current, enhanced deepwater ventilation, and poleward‐shifted southern westerly winds. In addition, the Sr‐Nd isotope signature of the detrital sediments indicates a shift in provenance around Marine Isotope Stage (MIS) 16, potentially linked to regional oceanic circulation changes. We suggest that an expanded Ross Gyre was important for controlling iceberg trajectories and sediment transport to the site before MIS 16, whereas modern‐like iceberg trajectories were established after MIS 16, probably related to a poleward shift of the Amundsen Sea Low after the end of the Mid‐Pleistocene Transition. This reorganization of the ocean and atmospheric circulation was followed by an interval of enhanced WAIS variability during MIS 15 to 13, which was linked to strong orbital and ocean forcing. These insights into the role of ocean‐atmosphere forcing on the past behavior of the WAIS may improve our framework for understanding future changes in this region.

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Interannual Variation of Modified Circumpolar Deep Water in the Dotson‐Getz Trough, West Antarctica

Cited by 26 publications

References 44 publications

Wind‐Induced Variability of Warm Water on the Southern Bellingshausen Sea Continental Shelf

Wind‐Induced Variability of Warm Water on the Southern Bellingshausen Sea Continental Shelf

Antarctic Peninsula warming triggers enhanced basal melt rates throughout West Antarctica

Ocean‐Forced Instability of the West Antarctic Ice Sheet Since the Mid‐Pleistocene

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