Assessing the potential for non-turbulent methane escape from the East Siberian Arctic Shelf

Matteo Puglini,Pierre Regnier,Sandra Arndt,Victor Brovkin

doi:10.5194/bg-17-3247-2020

Abstract

Abstract. The East Siberian Arctic Shelf (ESAS) hosts large yet poorly quantified reservoirs of subsea permafrost and associated gas hydrates. It has been suggested that the global-warming induced thawing and dissociation of these reservoirs is currently releasing methane (CH4) to the shallow coastal ocean and ultimately the atmosphere. However, a major unknown in assessing the contribution of this CH4 flux to the global CH4 cycle and its climate feedbacks is the fate of CH4 as it migrates towards the sediment–water interface. In marine sediments, (an)aerobic oxidation reactions generally act as a very efficient methane sink. However, a number of environmental conditions can reduce the efficiency of this biofilter. Here, we used a reaction-transport model to assess the efficiency of the benthic methane filter and, thus, the potential for benthic methane escape across a wide range of environmental conditions that could be encountered on the East Siberian Arctic Shelf. Results show that, under steady-state conditions, anaerobic oxidation of methane (AOM) acts as an efficient biofilter. However, high CH4 escape is simulated for rapidly accumulating and/or active sediments and can be further enhanced by the presence of organic matter with intermediate reactivity and/or intense local transport processes, such as bioirrigation. In addition, in active settings, the sudden onset of CH4 flux triggered by, for instance, permafrost thaw or hydrate destabilization can also drive a high non-turbulent methane escape of up to 19 µmol CH4 cm−2 yr−1 during a transient, multi-decadal period. This “window of opportunity” arises due to delayed response of the resident microbial community to suddenly changing CH4 fluxes. A first-order estimate of non-turbulent, benthic methane efflux from the Laptev Sea is derived as well. We find that, under present-day conditions, non-turbulent methane efflux from Laptev Sea sediments does not exceed 1 Gg CH4 yr−1. As a consequence, we conclude that previously published estimates of ocean–atmosphere CH4 fluxes from the ESAS cannot be supported by non-turbulent, benthic methane escape.

Highlights

The Siberian shelf represents the largest shelf on Earth (∼ 3 millions km2 Wegner et al, 2015) and spreads from the Kara Sea to the Laptev, East Siberian and Chuckhi seas
Model–data fitting highlights the important role of anaerobic oxidation of methane (AOM) in controlling the sulfate–methane transition zone (SMTZ), and indicates that upward migrating methane from deep, pre-Holocene sources, such as subsea permafrost in the sediment might be an ubiquitous feature on the Siberian shelf
We evaluate the potential for non-turbulent, benthic methane escape from thawing subsea permafrost and/or dissociating methane gas hydrates in both passive as well as active settings and under a range of environmental conditions that are broadly representative for conditions encountered on the present and future East Siberian Arctic Shelf (ESAS)

Summary

Introduction

The Siberian shelf represents the largest shelf on Earth (∼ 3 millions km Wegner et al, 2015) and spreads from the Kara Sea to the Laptev, East Siberian and Chuckhi seas. Subsea permafrost is a terrestrial relict that mainly formed during glacial periods, when retreating sea levels (with a minimum of 120 m below the current level around the Last Glacial Maximum) exposed Arctic shelves (Fairbanks, 1989; Bauch et al, 2001). Methane-concentrated formations in which a gas molecule is trapped in a cage of water molecules (Ruppel and Kessler, 2017) They are thermodynamically stable under specific temperature–pressure–salinity in the ocean floor, including areas beneath the subsea permafrost (Sloan and Koh, 2007)

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Conclusion