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Gas dynamics within landfast sea ice of an Arctic fjord (NE Greenland) during the spring–summer transition
Geilfus, N.-X.; Delille, B.; Tison, J.-L.; Lemes, M.; Rysgaard, S. (2023). Gas dynamics within landfast sea ice of an Arctic fjord (NE Greenland) during the spring–summer transition. Elem. Sci. Anth. 11(1): 00056. https://dx.doi.org/10.1525/elementa.2022.00056
In: Elementa Science of the Anthropocene. BioOne: Washington. e-ISSN 2325-1026, meer
Peer reviewed article  

Beschikbaar in  Auteurs 

Trefwoord
    Marien/Kust
Author keywords
    Sea ice, CO2, Gas, Melt ponds, Carbonate system

Auteurs  Top 
  • Geilfus, N.-X.
  • Delille, B., meer
  • Tison, J.-L., meer
  • Lemes, M.
  • Rysgaard, S.

Abstract
    Sea ice is an active component of the Earth’s climate system, interacting with both the atmosphere and the ocean. Arctic sea ice is commonly covered by melt ponds during late spring and summer, strongly affecting sea ice physical and optical properties. How melt pond formation affects sea ice gas dynamics and exchanges between sea ice and the atmosphere, with potential feedbacks on climate, is not well known. Here we measured concentrations of N2, O2, and Ar, total alkalinity, and dissolved inorganic carbon within sea ice of Young Sound, NE Greenland, to examine how melt pond formation and meltwater drainage through the ice affect its physical properties and gas composition, including impacts on CO2 exchange with the atmosphere. Sea ice gas composition was controlled mainly by physical processes, with most of the gas initially in gaseous form in the upper ice layer. A minor contribution from biological processes was associated with positive estimates of net community production (up to 2.6 µmol Lice−1 d−1), indicating that the ice was net autotrophic. As the sea ice warmed, the upper ice gas concentrations decreased, suggesting a release of gas bubbles to the atmosphere. However, as melt ponds formed, the ice surface became strongly depleted in gases. Due to melt pond development, meltwater permeated through the ice, resulting in the formation of an underwater ice layer also depleted in gases. Sea ice, including brine, slush, and melt ponds, was undersaturated in CO2 compared to the atmosphere, supporting an uptake of up to −4.26 mmol m−2 d−1 of atmospheric CO2. As melt pond formation progressed, however, this uptake weakened in the strongly altered remaining ice surface (the “white ice”), averaging −0.04 mmol m−2 d−1. This study reveals the importance of melt pond formation and dynamics for sea ice gas composition.

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