High-resolution under-water laser spectrometer sensing provides new insights to methane distribution at an Arctic seepage site

Jansson, Pär; Triest, Jack; Grilli, Roberto; Férré, Bénédicte; Silyakova, Anna; Mienert, Jürgen; Chappellaz, J.

doi:10.5194/os-2019-28

Cited by 2 publications

(2 citation statements)

References 32 publications

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“…90% of the methane seeping from marine sediments (Hinrichs and Boetius, 2002;Reeburgh, 2007;Knittel and Boetius, 2009) is microbially consumed close to the seafloor by the anaerobic oxidation of methane (AOM) consortium (Boetius et al, 2000). The remaining small fraction of methane escaping the sedimentary bio-filter is almost entirely oxidized by aerobic methane-oxidizing bacteria in the watercolumn before reaching the sea surface (McGinnis et al, 2006;Sparrow et al, 2018;Jansson et al, 2019). Methane-derived carbon is sequestered into authigenic carbonates precipitating within the sediment due to an alkalinity increase produced by the AOM consortium (CH 4 + SO 4 2− → HCO 3 − + HS − + H 2 O).…”

Section: Introductionmentioning

confidence: 99%

Biogeochemistry and timing of methane-derived carbonate formation at Leirdjupet fault complex, SW Barents sea

et al. 2022

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The origin of modern seafloor methane emissions in the Barents Sea is tightly connected to the glacio-tectonic and oceanographic transformations following the last ice age. Those regional events induced geological structure re-activation and destabilization of gas hydrate reservoirs over large areas of the European continental margins, sustaining widespread fluid plumbing systems. Despite the increasing number of new active seep discoveries, their accurate geochronology and paleo-dynamic is still poorly resolved, thus hindering precise identification of triggering factors and mechanisms controlling past and future seafloor emissions. Here, we report the distribution, petrographic (thin section, electron backscatter diffraction), isotopic (δ13C, δ18O) and lipid biomarker composition of methane-derived carbonates collected from Leirdjupet Fault Complex, SW Barents Sea, at 300 m depth during an ROV survey in 2021. Carbonates are located inside a 120 x 220 m elongated pockmark and form <10 m2 bodies protruding for about 2 m above the adjacent seafloor. Microstructural analyses of vein-filling cements showed the occurrence of three–five generations of isopachous aragonitic cement separated by dissolution surfaces indicative of intermittent oxidizing conditions. The integration of phase-specific isotopic analysis and U/Th dating showed δ13C values between −28.6‰ to −10.1‰ and δ18O between 4.6‰ and 5.3‰, enabling us to track carbonate mineral precipitation over the last ∼8 ka. Lipid biomarkers and their compound-specific δ13C analysis in the bulk carbonate revealed the presence of anaerobic methanotrophic archaea of the ANME-2 clade associated with sulfate-reducing bacteria of the Seep-SRB1 clade, as well as traces of petroleum. Our results indicate that methane and petroleum seepage in this area followed a similar evolution as in other southernmost Barents Sea sites controlled by the asynchronous deglaciation of the Barents Sea shelf, and that methane-derived carbonate precipitation is still an active process at many Arctic locations.

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Section: Introductionmentioning

confidence: 99%

Biogeochemistry and timing of methane-derived carbonate formation at Leirdjupet fault complex, SW Barents sea

et al. 2022

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“…The extraction system does not rely on gas equilibration across the membrane, but the dry side of the membrane is maintained at low pressure while continuously flushing it with dry zero air. This allows achieving fast response times < 30 sec, making the technique adapted for fast 3D mapping of water masses [21]. The accuracy (standard deviation at the three sigma level) of the measurements was quantified to be ± 33% from repeated measurements at the same depth.…”

Section: Measurement Methods Used By Cnrsmentioning

confidence: 99%

No increasing risk of a limnic eruption at Lake Kivu: Intercomparison study reveals gas concentrations close to steady state

et al. 2020

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Lake Kivu, East Africa, is well known for its huge reservoir of dissolved methane (CH 4) and carbon dioxide (CO 2) in the stratified deep waters (below 250 m). The methane concentrations of up to~20 mmol/l are sufficiently high for commercial gas extraction and power production. In view of the projected extraction capacity of up to several hundred MW in the next decades, reliable and accurate gas measurement techniques are required to closely monitor the evolution of gas concentrations. For this purpose, an intercomparison campaign for dissolved gas measurements was planned and conducted in March 2018. The applied measurement techniques included on-site mass spectrometry of continuously pumped sample water, gas chromatography of in-situ filled gas bags, an in-situ membrane inlet laser spectrometer sensor and a prototype sensor for total dissolved gas pressure (TDGP). We present the results of three datasets for CH 4 , two for CO 2 and one for TDGP. The resulting methane profiles show a good agreement within a range of around 5-10% in the deep water. We also observe that TDGP measurements in the deep waters are systematically around 5 to 10% lower than TDGP computed from gas concentrations. Part of this difference may be attributed to the non-trivial conversion of concentration to partial pressure in gasrich Lake Kivu. When comparing our data to past measurements, we cannot verify the previously suggested increase in methane concentrations since 1974. We therefore conclude that the methane and carbon dioxide concentrations in Lake Kivu are currently close to a steady state.

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High-resolution under-water laser spectrometer sensing provides new insights to methane distribution at an Arctic seepage site

Cited by 2 publications

References 32 publications

Biogeochemistry and timing of methane-derived carbonate formation at Leirdjupet fault complex, SW Barents sea

Biogeochemistry and timing of methane-derived carbonate formation at Leirdjupet fault complex, SW Barents sea

No increasing risk of a limnic eruption at Lake Kivu: Intercomparison study reveals gas concentrations close to steady state

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