Sources and sinks of methane in sea ice: Insights from stable isotopes

We report on methane (CH 4) stable isotope (d 13 C and d 2 H) measurements from landfast sea ice collected near Barrow (Utqiagvik, Alaska) and Cape Evans (Antarctica) over the winter-to-spring transition. These measurements provide novel insights into pathways of CH 4 production and consumption in s...

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Bibliographic Details
Published in:Elementa: Science of the Anthropocene
Main Authors: Jacques, Caroline, Sapart, Celia J., Fripiat, François, Carnat, Gauthier, Zhou, Jiayun, Delille, Bruno, Röckmann, Thomas, van der Veen, Carina, Niemann, Helge, Haskell, Tim, Tison, Jean-Louis
Format: Article in Journal/Newspaper
Language:English
Published: University of California Press 2021
Subjects:
VDP::Mathematics and natural science: 400::Geosciences: 450
VDP::Matematikk og Naturvitenskap: 400::Geofag: 450
Antarctic
Cape Evans
Mount Erebus
Antarc*
Antarctica
Arctic
Barrow
Sea ice
Alaska
Online Access:https://hdl.handle.net/10037/23138
https://doi.org/10.1525/elementa.2020.00167
Description
Summary:We report on methane (CH 4) stable isotope (d 13 C and d 2 H) measurements from landfast sea ice collected near Barrow (Utqiagvik, Alaska) and Cape Evans (Antarctica) over the winter-to-spring transition. These measurements provide novel insights into pathways of CH 4 production and consumption in sea ice. We found substantial differences between the two sites. Sea ice overlying the shallow shelf of Barrow was supersaturated in CH 4 with a clear microbial origin, most likely from methanogenesis in the sediments. We estimated that in situ CH 4 oxidation consumed a substantial fraction of the CH 4 being supplied to the sea ice, partly explaining the large range of isotopic values observed (d 13 C between –68.5 and –48.5 ‰ and d 2 H between –246 and –104 ‰). Sea ice at Cape Evans was also supersaturated in CH 4 but with surprisingly high d 13 C values (between –46.9 and –13.0 ‰), whereas d 2 H values (between –313 and –113 ‰) were in the range of those observed at Barrow.These are the first measurements of CH 4 isotopic composition in Antarctic sea ice. Our data set suggests a potential combination of a hydrothermal source, in the vicinity of the Mount Erebus, with aerobic CH 4 formation in sea ice, although the metabolic pathway for the latter still needs to be elucidated. Our observations show that sea ice needs to be considered as an active biogeochemical interface, contributing to CH 4 production and consumption, which disputes the standing paradigm that sea ice is an inert barrier passively accumulating CH 4 at the ocean-atmosphere boundary.

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