Image1_Methane pumping by rapidly refreezing lead ice in the ice-covered Arctic Ocean.JPEG

If and how the sea ice cycle drives the methane cycle in the high Arctic is an open question and crucial to improving source/sink balances. This study presents new insights into the effects of strong and fast freezing on the physical–chemical properties of ice and offers implications for methane flu...

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Main Authors: Ellen Damm, Silke Thoms, Michael Angelopoulos, Luisa Von Albedyll, Annette Rinke, Christian Haas
Format: Still Image
Language:unknown
Published: 2024
Subjects:
Solid Earth Sciences
Climate Science
Atmospheric Sciences not elsewhere classified
Exploration Geochemistry
Inorganic Geochemistry
Isotope Geochemistry
Organic Geochemistry
Geochemistry not elsewhere classified
Igneous and Metamorphic Petrology
Ore Deposit Petrology
Palaeontology (incl. Palynology)
Structural Geology
Tectonics
Volcanology
Geology not elsewhere classified
Seismology and Seismic Exploration
Glaciology
Hydrogeology
Natural Hazards
Quaternary Environments
Earth Sciences not elsewhere classified
Evolutionary Impacts of Climate Change
methane pathways in sea ice
methane exchange at interfaces
refrozen leads
polar winter study
methane isotopic signature
central Arctic Ocean
mosaic drift expedition
Arctic Ocean
Climate change
Sea ice
Online Access:https://doi.org/10.3389/feart.2024.1338246.s001
https://figshare.com/articles/figure/Image1_Methane_pumping_by_rapidly_refreezing_lead_ice_in_the_ice-covered_Arctic_Ocean_JPEG/25662096
id ftfrontimediafig:oai:figshare.com:article/25662096
record_format openpolar
spelling ftfrontimediafig:oai:figshare.com:article/25662096 2024-09-15T17:54:22+00:00 Image1_Methane pumping by rapidly refreezing lead ice in the ice-covered Arctic Ocean.JPEG Ellen Damm Silke Thoms Michael Angelopoulos Luisa Von Albedyll Annette Rinke Christian Haas 2024-04-22T04:11:35Z https://doi.org/10.3389/feart.2024.1338246.s001 https://figshare.com/articles/figure/Image1_Methane_pumping_by_rapidly_refreezing_lead_ice_in_the_ice-covered_Arctic_Ocean_JPEG/25662096 unknown doi:10.3389/feart.2024.1338246.s001 https://figshare.com/articles/figure/Image1_Methane_pumping_by_rapidly_refreezing_lead_ice_in_the_ice-covered_Arctic_Ocean_JPEG/25662096 CC BY 4.0 Solid Earth Sciences Climate Science Atmospheric Sciences not elsewhere classified Exploration Geochemistry Inorganic Geochemistry Isotope Geochemistry Organic Geochemistry Geochemistry not elsewhere classified Igneous and Metamorphic Petrology Ore Deposit Petrology Palaeontology (incl. Palynology) Structural Geology Tectonics Volcanology Geology not elsewhere classified Seismology and Seismic Exploration Glaciology Hydrogeology Natural Hazards Quaternary Environments Earth Sciences not elsewhere classified Evolutionary Impacts of Climate Change methane pathways in sea ice methane exchange at interfaces refrozen leads polar winter study methane isotopic signature central Arctic Ocean mosaic drift expedition Image Figure 2024 ftfrontimediafig https://doi.org/10.3389/feart.2024.1338246.s001 2024-08-19T06:19:45Z If and how the sea ice cycle drives the methane cycle in the high Arctic is an open question and crucial to improving source/sink balances. This study presents new insights into the effects of strong and fast freezing on the physical–chemical properties of ice and offers implications for methane fluxes into and out of newly formed lead ice. During the 2019–2020 transpolar drift of the Multidisciplinary Drifting Observatory for the Study of Arctic Climate (MOSAiC), we took weekly samples of growing lead ice and underlying seawater at the same site between January and March 2020. We analyzed concentrations and stable carbon isotopic signatures (δ 13 C–CH 4 ) of methane and calculated methane solubility capacities (MSC) and saturation levels in both environments. During the first month, intense cooling resulted in the growth of two-thirds of the final ice thickness. In the second month, ice growth speed decreased by 50%. Both growth phases, disentangled, exposed different freeze impacts on methane pathways. The fast freeze caused strong brine entrapment, keeping the newly formed lead ice permeable for 2 weeks. These physical conditions activated a methane pump. An increased MSC induced methane uptake at the air–ice interface, and the still-open brine channels provided top-down transport to the ocean interface with brine drainage. When the subsurface layer became impermeable, the top-down pumping stopped, but the ongoing uptake induced a methane excess on top. During the second growth phase, methane exchange exclusively continued at the ice–ocean interface. The shift in the relative abundance of the 12 C and 13 C isotopes between lead ice and seawater toward a 13 C-enrichment in seawater reveals brine drainage as the main pathway releasing methane from aging lead ice. We conclude that in winter, refrozen leads temporarily function as active sinks for atmospheric methane and postulate that the relevance of this process may even increase when the Arctic fully transitions into a seasonally ice-covered ocean when leads ... Still Image Arctic Ocean Climate change Sea ice Frontiers: Figshare
institution Open Polar
collection Frontiers: Figshare
op_collection_id ftfrontimediafig
language unknown
topic Solid Earth Sciences
Climate Science
Atmospheric Sciences not elsewhere classified
Exploration Geochemistry
Inorganic Geochemistry
Isotope Geochemistry
Organic Geochemistry
Geochemistry not elsewhere classified
Igneous and Metamorphic Petrology
Ore Deposit Petrology
Palaeontology (incl. Palynology)
Structural Geology
Tectonics
Volcanology
Geology not elsewhere classified
Seismology and Seismic Exploration
Glaciology
Hydrogeology
Natural Hazards
Quaternary Environments
Earth Sciences not elsewhere classified
Evolutionary Impacts of Climate Change
methane pathways in sea ice
methane exchange at interfaces
refrozen leads
polar winter study
methane isotopic signature
central Arctic Ocean
mosaic drift expedition
spellingShingle Solid Earth Sciences
Climate Science
Atmospheric Sciences not elsewhere classified
Exploration Geochemistry
Inorganic Geochemistry
Isotope Geochemistry
Organic Geochemistry
Geochemistry not elsewhere classified
Igneous and Metamorphic Petrology
Ore Deposit Petrology
Palaeontology (incl. Palynology)
Structural Geology
Tectonics
Volcanology
Geology not elsewhere classified
Seismology and Seismic Exploration
Glaciology
Hydrogeology
Natural Hazards
Quaternary Environments
Earth Sciences not elsewhere classified
Evolutionary Impacts of Climate Change
methane pathways in sea ice
methane exchange at interfaces
refrozen leads
polar winter study
methane isotopic signature
central Arctic Ocean
mosaic drift expedition
Ellen Damm
Silke Thoms
Michael Angelopoulos
Luisa Von Albedyll
Annette Rinke
Christian Haas
Image1_Methane pumping by rapidly refreezing lead ice in the ice-covered Arctic Ocean.JPEG
topic_facet Solid Earth Sciences
Climate Science
Atmospheric Sciences not elsewhere classified
Exploration Geochemistry
Inorganic Geochemistry
Isotope Geochemistry
Organic Geochemistry
Geochemistry not elsewhere classified
Igneous and Metamorphic Petrology
Ore Deposit Petrology
Palaeontology (incl. Palynology)
Structural Geology
Tectonics
Volcanology
Geology not elsewhere classified
Seismology and Seismic Exploration
Glaciology
Hydrogeology
Natural Hazards
Quaternary Environments
Earth Sciences not elsewhere classified
Evolutionary Impacts of Climate Change
methane pathways in sea ice
methane exchange at interfaces
refrozen leads
polar winter study
methane isotopic signature
central Arctic Ocean
mosaic drift expedition
description If and how the sea ice cycle drives the methane cycle in the high Arctic is an open question and crucial to improving source/sink balances. This study presents new insights into the effects of strong and fast freezing on the physical–chemical properties of ice and offers implications for methane fluxes into and out of newly formed lead ice. During the 2019–2020 transpolar drift of the Multidisciplinary Drifting Observatory for the Study of Arctic Climate (MOSAiC), we took weekly samples of growing lead ice and underlying seawater at the same site between January and March 2020. We analyzed concentrations and stable carbon isotopic signatures (δ 13 C–CH 4 ) of methane and calculated methane solubility capacities (MSC) and saturation levels in both environments. During the first month, intense cooling resulted in the growth of two-thirds of the final ice thickness. In the second month, ice growth speed decreased by 50%. Both growth phases, disentangled, exposed different freeze impacts on methane pathways. The fast freeze caused strong brine entrapment, keeping the newly formed lead ice permeable for 2 weeks. These physical conditions activated a methane pump. An increased MSC induced methane uptake at the air–ice interface, and the still-open brine channels provided top-down transport to the ocean interface with brine drainage. When the subsurface layer became impermeable, the top-down pumping stopped, but the ongoing uptake induced a methane excess on top. During the second growth phase, methane exchange exclusively continued at the ice–ocean interface. The shift in the relative abundance of the 12 C and 13 C isotopes between lead ice and seawater toward a 13 C-enrichment in seawater reveals brine drainage as the main pathway releasing methane from aging lead ice. We conclude that in winter, refrozen leads temporarily function as active sinks for atmospheric methane and postulate that the relevance of this process may even increase when the Arctic fully transitions into a seasonally ice-covered ocean when leads ...
format Still Image
author Ellen Damm
Silke Thoms
Michael Angelopoulos
Luisa Von Albedyll
Annette Rinke
Christian Haas
author_facet Ellen Damm
Silke Thoms
Michael Angelopoulos
Luisa Von Albedyll
Annette Rinke
Christian Haas
author_sort Ellen Damm
title Image1_Methane pumping by rapidly refreezing lead ice in the ice-covered Arctic Ocean.JPEG
title_short Image1_Methane pumping by rapidly refreezing lead ice in the ice-covered Arctic Ocean.JPEG
title_full Image1_Methane pumping by rapidly refreezing lead ice in the ice-covered Arctic Ocean.JPEG
title_fullStr Image1_Methane pumping by rapidly refreezing lead ice in the ice-covered Arctic Ocean.JPEG
title_full_unstemmed Image1_Methane pumping by rapidly refreezing lead ice in the ice-covered Arctic Ocean.JPEG
title_sort image1_methane pumping by rapidly refreezing lead ice in the ice-covered arctic ocean.jpeg
publishDate 2024
url https://doi.org/10.3389/feart.2024.1338246.s001
https://figshare.com/articles/figure/Image1_Methane_pumping_by_rapidly_refreezing_lead_ice_in_the_ice-covered_Arctic_Ocean_JPEG/25662096
genre Arctic Ocean
Climate change
Sea ice
genre_facet Arctic Ocean
Climate change
Sea ice
op_relation doi:10.3389/feart.2024.1338246.s001
https://figshare.com/articles/figure/Image1_Methane_pumping_by_rapidly_refreezing_lead_ice_in_the_ice-covered_Arctic_Ocean_JPEG/25662096
op_rights CC BY 4.0
op_doi https://doi.org/10.3389/feart.2024.1338246.s001
_version_ 1810430667027120128

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