Submarine Permafrost on the Siberian Shelf

Recent results include the publication of drilling results from the central Laptev Sea, carried out by a consortium of partners from t. Petersburg (Arctic and Antarctic Research Institute), Yakutsk (Mel’nikov Permafrost Institute), the Universities of Hamburg and Potsdam, and two Potsdam research in...

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Main Authors: Hubberten, Hans-Wolfgang, Overduin, Paul, Grigoriev, M. N.
Format: Conference Object
Language:unknown
Published: 2015
Subjects:
Antarctic
Arctic
Laptev Sea
Thornton
Yakutsk
Antarc*
Arctic and Antarctic Research Institute
Climate change
Ice
laptev
permafrost
Siberia
Online Access:https://epic.awi.de/id/eprint/47602/
https://epic.awi.de/id/eprint/47602/1/OverduinWTZ2015.pdf
https://hdl.handle.net/10013/epic.405c679f-fea2-4bfc-8fbf-090e87e45c59
https://hdl.handle.net/
id ftawi:oai:epic.awi.de:47602
record_format openpolar
institution Open Polar
collection Alfred Wegener Institute for Polar- and Marine Research (AWI): ePIC (electronic Publication Information Center)
op_collection_id ftawi
language unknown
description Recent results include the publication of drilling results from the central Laptev Sea, carried out by a consortium of partners from t. Petersburg (Arctic and Antarctic Research Institute), Yakutsk (Mel’nikov Permafrost Institute), the Universities of Hamburg and Potsdam, and two Potsdam research institutes (Alfred Wegener Institute, Geoforschungszentrum). We were able to measure methane concentrations within thawing but still frozen submarine permafrost. Based on approximate duration of inundation, it was possible to estimate rates of methane release (Overduin et al. 2015). Surprisingly, however, methane from permafrost did not migrate to the sea bed, but was oxidized by bacteria within the unfrozen sediment on top of the frozen permafrost (see Nature Climate Change comment on our work: Thornton and Crill, 2015). In further work, results of the innovative passive seismic method for detection of frozen submarine permafrost were published, detailing the method and first results. Modelling demonstrated that the observed signals correlate with the depth of unfrozen sediment overlying the ice-bonded permafrost (Overduin et al. 2015). This method is promising, since it has no impact on the seabed or biota, and can be operated without disturbing marine mammals. The next steps are to develop the instruments for operation over larger regions and for a wider range of permafrost depths. Real time operation (as opposed to deployment with autonomous logging) promises to speed up measurement, an important consideration for the large area of the Siberian shelf. Part of 2015 was occupied with proposal-writing to obtain support for this instrument development and testing in Siberia; the review process is on-going. Modelling efforts continue, together with a new partner, Climate Analytics GmbH in Berlin. A functioning model of submarine permafrost has been developed and is currently being tested. The goal is to develop a circum-arctic understanding of permafrost development over glacial-interglacial cycles. The first stage of modelling is expected to be completed by the end of the year, with results to be publicized at next year’s 11th International Conference on Permafrost in Potsdam, Germany. References Overduin, P. P., C. Haberland, T. Ryberg, F. Kneier, T. Jacobi, M. N. Grigoriev, and M. Ohrnberger (2015), Submarine permafrost depth from ambient seismic noise, Geophys. Res. Lett., 42, doi:10.1002/2015GL065409. Overduin, P. P., Liebner, S. , Knoblauch, C. , Günther, F. , Wetterich, S. , Schirrmeister, L. , Hubberten, H. W. and Grigoriev, M. N. (2015), Methane oxidation following submarine permafrost degradation: Measurements from a central Laptev Sea shelf borehole, Journal of Geophysical Research: Biogeosciences, 120 (5), pp. 965-978, doi:10.1002/2014JG002862. Thornton, B. F., and Crill, P. (2015), Arctic Permafrost: Microbial lid on subsea methane, Nature Climate Change, 5: 723-724.
format Conference Object
author Hubberten, Hans-Wolfgang
Overduin, Paul
Grigoriev, M. N.
spellingShingle Hubberten, Hans-Wolfgang
Overduin, Paul
Grigoriev, M. N.
Submarine Permafrost on the Siberian Shelf
author_facet Hubberten, Hans-Wolfgang
Overduin, Paul
Grigoriev, M. N.
author_sort Hubberten, Hans-Wolfgang
title Submarine Permafrost on the Siberian Shelf
title_short Submarine Permafrost on the Siberian Shelf
title_full Submarine Permafrost on the Siberian Shelf
title_fullStr Submarine Permafrost on the Siberian Shelf
title_full_unstemmed Submarine Permafrost on the Siberian Shelf
title_sort submarine permafrost on the siberian shelf
publishDate 2015
url https://epic.awi.de/id/eprint/47602/
https://epic.awi.de/id/eprint/47602/1/OverduinWTZ2015.pdf
https://hdl.handle.net/10013/epic.405c679f-fea2-4bfc-8fbf-090e87e45c59
https://hdl.handle.net/
long_lat ENVELOPE(-57.467,-57.467,-63.267,-63.267)
geographic Antarctic
Arctic
Laptev Sea
Thornton
Yakutsk
geographic_facet Antarctic
Arctic
Laptev Sea
Thornton
Yakutsk
genre Antarc*
Antarctic
Arctic and Antarctic Research Institute
Arctic
Climate change
Ice
laptev
Laptev Sea
permafrost
Yakutsk
Siberia
genre_facet Antarc*
Antarctic
Arctic and Antarctic Research Institute
Arctic
Climate change
Ice
laptev
Laptev Sea
permafrost
Yakutsk
Siberia
op_source EPIC3Wissenschaftlich-Technischen Zusammenarbeit (WTZ) auf dem Gebiet der Polar- und Meeresforschung mit der Russischen Föderation, St. Petersburg, Russia, 2015-10-21-2015-10-22
op_relation https://epic.awi.de/id/eprint/47602/1/OverduinWTZ2015.pdf
https://hdl.handle.net/
Hubberten, H. W. , Overduin, P. orcid:0000-0001-9849-4712 and Grigoriev, M. N. (2015) Submarine Permafrost on the Siberian Shelf , Wissenschaftlich-Technischen Zusammenarbeit (WTZ) auf dem Gebiet der Polar- und Meeresforschung mit der Russischen Föderation, St. Petersburg, Russia, 21 October 2015 - 22 October 2015 . hdl:10013/epic.405c679f-fea2-4bfc-8fbf-090e87e45c59
_version_ 1766221289909911552
spelling ftawi:oai:epic.awi.de:47602 2023-05-15T13:45:21+02:00 Submarine Permafrost on the Siberian Shelf Hubberten, Hans-Wolfgang Overduin, Paul Grigoriev, M. N. 2015-10 application/pdf https://epic.awi.de/id/eprint/47602/ https://epic.awi.de/id/eprint/47602/1/OverduinWTZ2015.pdf https://hdl.handle.net/10013/epic.405c679f-fea2-4bfc-8fbf-090e87e45c59 https://hdl.handle.net/ unknown https://epic.awi.de/id/eprint/47602/1/OverduinWTZ2015.pdf https://hdl.handle.net/ Hubberten, H. W. , Overduin, P. orcid:0000-0001-9849-4712 and Grigoriev, M. N. (2015) Submarine Permafrost on the Siberian Shelf , Wissenschaftlich-Technischen Zusammenarbeit (WTZ) auf dem Gebiet der Polar- und Meeresforschung mit der Russischen Föderation, St. Petersburg, Russia, 21 October 2015 - 22 October 2015 . hdl:10013/epic.405c679f-fea2-4bfc-8fbf-090e87e45c59 EPIC3Wissenschaftlich-Technischen Zusammenarbeit (WTZ) auf dem Gebiet der Polar- und Meeresforschung mit der Russischen Föderation, St. Petersburg, Russia, 2015-10-21-2015-10-22 Conference notRev 2015 ftawi 2021-12-24T15:44:00Z Recent results include the publication of drilling results from the central Laptev Sea, carried out by a consortium of partners from t. Petersburg (Arctic and Antarctic Research Institute), Yakutsk (Mel’nikov Permafrost Institute), the Universities of Hamburg and Potsdam, and two Potsdam research institutes (Alfred Wegener Institute, Geoforschungszentrum). We were able to measure methane concentrations within thawing but still frozen submarine permafrost. Based on approximate duration of inundation, it was possible to estimate rates of methane release (Overduin et al. 2015). Surprisingly, however, methane from permafrost did not migrate to the sea bed, but was oxidized by bacteria within the unfrozen sediment on top of the frozen permafrost (see Nature Climate Change comment on our work: Thornton and Crill, 2015). In further work, results of the innovative passive seismic method for detection of frozen submarine permafrost were published, detailing the method and first results. Modelling demonstrated that the observed signals correlate with the depth of unfrozen sediment overlying the ice-bonded permafrost (Overduin et al. 2015). This method is promising, since it has no impact on the seabed or biota, and can be operated without disturbing marine mammals. The next steps are to develop the instruments for operation over larger regions and for a wider range of permafrost depths. Real time operation (as opposed to deployment with autonomous logging) promises to speed up measurement, an important consideration for the large area of the Siberian shelf. Part of 2015 was occupied with proposal-writing to obtain support for this instrument development and testing in Siberia; the review process is on-going. Modelling efforts continue, together with a new partner, Climate Analytics GmbH in Berlin. A functioning model of submarine permafrost has been developed and is currently being tested. The goal is to develop a circum-arctic understanding of permafrost development over glacial-interglacial cycles. The first stage of modelling is expected to be completed by the end of the year, with results to be publicized at next year’s 11th International Conference on Permafrost in Potsdam, Germany. References Overduin, P. P., C. Haberland, T. Ryberg, F. Kneier, T. Jacobi, M. N. Grigoriev, and M. Ohrnberger (2015), Submarine permafrost depth from ambient seismic noise, Geophys. Res. Lett., 42, doi:10.1002/2015GL065409. Overduin, P. P., Liebner, S. , Knoblauch, C. , Günther, F. , Wetterich, S. , Schirrmeister, L. , Hubberten, H. W. and Grigoriev, M. N. (2015), Methane oxidation following submarine permafrost degradation: Measurements from a central Laptev Sea shelf borehole, Journal of Geophysical Research: Biogeosciences, 120 (5), pp. 965-978, doi:10.1002/2014JG002862. Thornton, B. F., and Crill, P. (2015), Arctic Permafrost: Microbial lid on subsea methane, Nature Climate Change, 5: 723-724. Conference Object Antarc* Antarctic Arctic and Antarctic Research Institute Arctic Climate change Ice laptev Laptev Sea permafrost Yakutsk Siberia Alfred Wegener Institute for Polar- and Marine Research (AWI): ePIC (electronic Publication Information Center) Antarctic Arctic Laptev Sea Thornton ENVELOPE(-57.467,-57.467,-63.267,-63.267) Yakutsk

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