Influence of Shelf Break Processes on the Transport of Warm Waters Onto the Eastern Amundsen Sea Continental Shelf

The heat transported onto the continental shelf by Circumpolar Deep Water (CDW) is the main driver of ice shelf basal melting in the Amundsen Sea. Here, we investigate the slope current system and the variability of the heat transported through the Pine Island‐Thwaites central and eastern troughs us...

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Bibliographic Details
Published in:Journal of geophysical research. Oceans 2023-05, Vol.128 (5), p.n/a
Main Authors: Azaneu, Marina, Webber, Benjamin, Heywood, Karen J., Assmann, Karen M., Dotto, Tiago S., Abrahamsen, E. Povl
Format: Article
Language:English
Subjects:
Antarctic oceanography
Atmospheric forcing
Coastal currents
Continental shelves
Deep water
El Nino
El Nino events
El Nino phenomena
Enthalpy
Floating ice
Fluctuations
Geophysics
Glacier melting
Glaciers
Heat
Heat content
Heat flux
Heat transfer
heat transport
Ice
Ice shelves
interannual variability
Land ice
Local winds
Low temperature
Melting
Mooring
Ocean circulation
Ocean currents
Ocean temperature
Oceanografi, hydrologi, vattenresurser
Oceanography, Hydrology, Water Resources
Oceans
Sea currents
Shelf dynamics
Slope currents
Southern Oscillation
Surface wind
Transport
Troughs
Undercurrents
Upwelling
Variability
Warm currents
Westerlies
Wind
Wind stress
Zonal winds
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Summary:The heat transported onto the continental shelf by Circumpolar Deep Water (CDW) is the main driver of ice shelf basal melting in the Amundsen Sea. Here, we investigate the slope current system and the variability of the heat transported through the Pine Island‐Thwaites central and eastern troughs using data from five moorings deployed in the region between 5 March 2012 and 7 February 2016. Substantial variability on intermonthly time scales (3–4 months) is observed in the onshore heat flux, driven primarily by zonal wind stress north of the shelf break. Heat content, onshore flow, and heat flux are highly correlated between central and eastern troughs, which are most likely dynamically linked by the zonal wind stress forcing. This is the first time this dynamic link between troughs is observed. In the eastern the Amundsen Sea, during the El Niño of 2015/2016, strong eastward winds led to lower temperatures over the continental shelf while the onshore heat flux is intensified. We hypothesize that this anti‐correlation between heat content and heat flux results from a strengthened eastward undercurrent leading to upwelling of a colder and deeper CDW variety. These results highlight the complex and heterogeneous response of this region to environmental and the importance of velocity data for understanding the dynamics in this region. It also suggests that the hypothesized link between large‐scale atmospheric forcing (e.g., El Niño‐Southern Oscillation) and ice‐shelf melt is not produced via changes in heat content, but instead via changes in onshore heat flux. Plain Language Summary Heat stored in the ocean is the main reason that floating ice attached to the glaciers that surround the Amundsen Sea is melting. We investigate how the strength of coastal currents and the amount of heat transported by them toward the Antarctic shore vary in time. We use continuous measurements for up to 4 yr of ocean currents at five different locations in the Amundsen Sea. The amount of heat transported by a relatively warm current varies mostly with a 3–4 months period, which is influenced by local surface winds. These are the first observations showing consistency in the variability of heat transported toward the shore across different locations in this region. Moreover, we show that changes in the local winds related to the El Niño event of 2015/2016 led to a period of low ocean temperatures and enhanced transport of heat toward the shore. We explain this contradictory behav
ISSN:2169-9275
2169-9291
DOI:10.1029/2022JC019535