Estimates of future warming-induced methane emissions from hydrate offshore west Svalbard for a range of climate models
Estimates of future warming-induced methane emissions from hydrate offshore west Svalbard for a range of climate models
Methane hydrate close to the hydrate stability limit in seafloor sediment could represent an important source of methane to the oceans and atmosphere as the oceans warm. We investigate the extent to which patterns of past and future ocean-temperature fluctuations influence hydrate stability in a region offshore West Svalbard where active gas venting has been observed. We model the transient behavior of the gas hydrate stability zone at 400-500 m water depth (mwd) in response to past temperature changes inferred from historical measurements and proxy data and we model future changes predicted by seven climate models and two climate-forcing scenarios (Representative Concentration Pathways RCPs 2.6 and 8.5). We show that over the past 2000 year, a combination of annual and decadal temperature fluctuations could have triggered multiple hydrate-sourced methane emissions from seabed shallower than 400 mwd during episodes when the multidecadal average temperature was similar to that over the last century (∼2.6°C). These temperature fluctuations can explain current methane emissions at 400 mwd, but decades to centuries of ocean warming are required to generate emissions in water deeper than 420 m. In the venting area, future methane emissions are relatively insensitive to the choice of climate model and RCP scenario until 2050 year, but are more sensitive to the RCP scenario after 2050 year. By 2100 CE, we estimate an ocean uptake of 97-1050 TgC from marine Arctic hydrate-sourced methane emissions, which is 0.06-0.67% of the ocean uptake from anthropogenic CO2 emissions for the period 1750-2011. Key Points: CH4 emissions offshore Svalbard insensitive to RCP and climate models by 2050 CE Temperature fluctuations likely triggered past CH4 emissions offshore Svalbard Average CO2 ocean uptake from Arctic hydrate dissociation of 97-1050 TgC by 2100
gas hydrates, ocean warming, global climate models, modeling
1307-1323
Marín-Moreno, Héctor
e466cafd-bd5c-47a1-8522-e6938e7086a4
Minshull, Timothy A.
bf413fb5-849e-4389-acd7-0cb0d644e6b8
Westbrook, Graham K.
ccd95de7-a1a1-4fc9-be37-f1a487bb65ca
Sinha, Bablu
fbb0cf78-c13b-43e0-b0ae-735ca4d4cded
8 May 2015
Marín-Moreno, Héctor
e466cafd-bd5c-47a1-8522-e6938e7086a4
Minshull, Timothy A.
bf413fb5-849e-4389-acd7-0cb0d644e6b8
Westbrook, Graham K.
ccd95de7-a1a1-4fc9-be37-f1a487bb65ca
Sinha, Bablu
fbb0cf78-c13b-43e0-b0ae-735ca4d4cded
Marín-Moreno, Héctor, Minshull, Timothy A., Westbrook, Graham K. and Sinha, Bablu
(2015)
Estimates of future warming-induced methane emissions from hydrate offshore west Svalbard for a range of climate models.
Geochemistry, Geophysics, Geosystems, 16 (5), .
(doi:10.1002/2015GC005737).
Abstract
Methane hydrate close to the hydrate stability limit in seafloor sediment could represent an important source of methane to the oceans and atmosphere as the oceans warm. We investigate the extent to which patterns of past and future ocean-temperature fluctuations influence hydrate stability in a region offshore West Svalbard where active gas venting has been observed. We model the transient behavior of the gas hydrate stability zone at 400-500 m water depth (mwd) in response to past temperature changes inferred from historical measurements and proxy data and we model future changes predicted by seven climate models and two climate-forcing scenarios (Representative Concentration Pathways RCPs 2.6 and 8.5). We show that over the past 2000 year, a combination of annual and decadal temperature fluctuations could have triggered multiple hydrate-sourced methane emissions from seabed shallower than 400 mwd during episodes when the multidecadal average temperature was similar to that over the last century (∼2.6°C). These temperature fluctuations can explain current methane emissions at 400 mwd, but decades to centuries of ocean warming are required to generate emissions in water deeper than 420 m. In the venting area, future methane emissions are relatively insensitive to the choice of climate model and RCP scenario until 2050 year, but are more sensitive to the RCP scenario after 2050 year. By 2100 CE, we estimate an ocean uptake of 97-1050 TgC from marine Arctic hydrate-sourced methane emissions, which is 0.06-0.67% of the ocean uptake from anthropogenic CO2 emissions for the period 1750-2011. Key Points: CH4 emissions offshore Svalbard insensitive to RCP and climate models by 2050 CE Temperature fluctuations likely triggered past CH4 emissions offshore Svalbard Average CO2 ocean uptake from Arctic hydrate dissociation of 97-1050 TgC by 2100
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Mar%EDn_Moreno_et_al-2015-Geochemistry,_Geophysics,_Geosystems.pdf
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Accepted/In Press date: 5 April 2015
e-pub ahead of print date: 10 April 2015
Published date: 8 May 2015
Keywords:
gas hydrates, ocean warming, global climate models, modeling
Organisations:
Marine Systems Modelling, Geology & Geophysics, Marine Geoscience
Identifiers
Local EPrints ID: 376954
URI: http://eprints.soton.ac.uk/id/eprint/376954
ISSN: 1525-2027
PURE UUID: c09ea708-288b-4b27-80a1-508bd174f6a9
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Date deposited: 11 May 2015 09:28
Last modified: 15 Mar 2024 04:14
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Author:
Héctor Marín-Moreno
Author:
Bablu Sinha
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