Observation-based modelling of permafrost carbon fluxes with accounting for deep carbon deposits and thermokarst activity

High-latitude soils store vast amounts of perennially frozen and therefore inert organic matter. With rising global temperatures and consequent permafrost degradation, a part of this carbon stock will become available for microbial decay and eventual release to the atmosphere. We have developed a si...

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Main Authors: Schneider Von Deimling, T., Grosse, G., Strauss, J., Schirrmeister, L., Morgenstern, A., Schaphoff, S., Meinshausen, M., Boike, J.
Format: Article in Journal/Newspaper
Language:English
Published: München : European Geopyhsical Union 2015
Subjects:
carbon dioxide
carbon flux
emission
freeze-thaw cycle
lacustrine deposit
methane
observational method
organic matter permafrost
Pleistocene
radiative forcing
thermokarst
warming
550
permafrost
Thermokarst
Online Access:https://dx.doi.org/10.34657/1134
https://oa.tib.eu/renate/handle/123456789/565
id ftdatacite:10.34657/1134
record_format openpolar
spelling ftdatacite:10.34657/1134 2023-05-15T17:55:52+02:00 Observation-based modelling of permafrost carbon fluxes with accounting for deep carbon deposits and thermokarst activity Schneider Von Deimling, T. Grosse, G. Strauss, J. Schirrmeister, L. Morgenstern, A. Schaphoff, S. Meinshausen, M. Boike, J. 2015 application/pdf https://dx.doi.org/10.34657/1134 https://oa.tib.eu/renate/handle/123456789/565 en eng München : European Geopyhsical Union Creative Commons Attribution 3.0 Unported CC BY 3.0 Unported https://creativecommons.org/licenses/by/3.0/legalcode cc-by-3.0 CC-BY carbon dioxide carbon flux emission freeze-thaw cycle lacustrine deposit methane observational method organic matter permafrost Pleistocene radiative forcing thermokarst warming 550 CreativeWork article Other 2015 ftdatacite https://doi.org/10.34657/1134 2022-03-10T12:42:45Z High-latitude soils store vast amounts of perennially frozen and therefore inert organic matter. With rising global temperatures and consequent permafrost degradation, a part of this carbon stock will become available for microbial decay and eventual release to the atmosphere. We have developed a simplified, two-dimensional multi-pool model to estimate the strength and timing of future carbon dioxide (CO2) and methane (CH4) fluxes from newly thawed permafrost carbon (i.e. carbon thawed when temperatures rise above pre-industrial levels). We have especially simulated carbon release from deep deposits in Yedoma regions by describing abrupt thaw under newly formed thermokarst lakes. The computational efficiency of our model allowed us to run large, multi-centennial ensembles under various scenarios of future warming to express uncertainty inherent to simulations of the permafrost carbon feedback. Under moderate warming of the representative concentration pathway (RCP) 2.6 scenario, cumulated CO2 fluxes from newly thawed permafrost carbon amount to 20 to 58 petagrams of carbon (Pg-C) (68% range) by the year 2100 and reach 40 to 98 Pg-C in 2300. The much larger permafrost degradation under strong warming (RCP8.5) results in cumulated CO2 release of 42 to 141 Pg-C and 157 to 313 Pg-C (68% ranges) in the years 2100 and 2300, respectively. Our estimates only consider fluxes from newly thawed permafrost, not from soils already part of the seasonally thawed active layer under pre-industrial climate. Our simulated CH4 fluxes contribute a few percent to total permafrost carbon release yet they can cause up to 40% of total permafrost-affected radiative forcing in the 21st century (upper 68% range). We infer largest CH4 emission rates of about 50 Tg-CH4 per year around the middle of the 21st century when simulated thermokarst lake extent is at its maximum and when abrupt thaw under thermokarst lakes is taken into account. CH4 release from newly thawed carbon in wetland-affected deposits is only discernible in the 22nd and 23rd century because of the absence of abrupt thaw processes. We further show that release from organic matter stored in deep deposits of Yedoma regions crucially affects our simulated circumpolar CH4 fluxes. The additional warming through the release from newly thawed permafrost carbon proved only slightly dependent on the pathway of anthropogenic emission and amounts to about 0.03–0.14 °C (68% ranges) by end of the century. The warming increased further in the 22nd and 23rd century and was most pronounced under the RCP6.0 scenario, adding 0.16 to 0.39 °C (68% range) to simulated global mean surface air temperatures in the year 2300. Article in Journal/Newspaper permafrost Thermokarst DataCite Metadata Store (German National Library of Science and Technology)
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language English
topic carbon dioxide
carbon flux
emission
freeze-thaw cycle
lacustrine deposit
methane
observational method
organic matter permafrost
Pleistocene
radiative forcing
thermokarst
warming
550
spellingShingle carbon dioxide
carbon flux
emission
freeze-thaw cycle
lacustrine deposit
methane
observational method
organic matter permafrost
Pleistocene
radiative forcing
thermokarst
warming
550
Schneider Von Deimling, T.
Grosse, G.
Strauss, J.
Schirrmeister, L.
Morgenstern, A.
Schaphoff, S.
Meinshausen, M.
Boike, J.
Observation-based modelling of permafrost carbon fluxes with accounting for deep carbon deposits and thermokarst activity
topic_facet carbon dioxide
carbon flux
emission
freeze-thaw cycle
lacustrine deposit
methane
observational method
organic matter permafrost
Pleistocene
radiative forcing
thermokarst
warming
550
description High-latitude soils store vast amounts of perennially frozen and therefore inert organic matter. With rising global temperatures and consequent permafrost degradation, a part of this carbon stock will become available for microbial decay and eventual release to the atmosphere. We have developed a simplified, two-dimensional multi-pool model to estimate the strength and timing of future carbon dioxide (CO2) and methane (CH4) fluxes from newly thawed permafrost carbon (i.e. carbon thawed when temperatures rise above pre-industrial levels). We have especially simulated carbon release from deep deposits in Yedoma regions by describing abrupt thaw under newly formed thermokarst lakes. The computational efficiency of our model allowed us to run large, multi-centennial ensembles under various scenarios of future warming to express uncertainty inherent to simulations of the permafrost carbon feedback. Under moderate warming of the representative concentration pathway (RCP) 2.6 scenario, cumulated CO2 fluxes from newly thawed permafrost carbon amount to 20 to 58 petagrams of carbon (Pg-C) (68% range) by the year 2100 and reach 40 to 98 Pg-C in 2300. The much larger permafrost degradation under strong warming (RCP8.5) results in cumulated CO2 release of 42 to 141 Pg-C and 157 to 313 Pg-C (68% ranges) in the years 2100 and 2300, respectively. Our estimates only consider fluxes from newly thawed permafrost, not from soils already part of the seasonally thawed active layer under pre-industrial climate. Our simulated CH4 fluxes contribute a few percent to total permafrost carbon release yet they can cause up to 40% of total permafrost-affected radiative forcing in the 21st century (upper 68% range). We infer largest CH4 emission rates of about 50 Tg-CH4 per year around the middle of the 21st century when simulated thermokarst lake extent is at its maximum and when abrupt thaw under thermokarst lakes is taken into account. CH4 release from newly thawed carbon in wetland-affected deposits is only discernible in the 22nd and 23rd century because of the absence of abrupt thaw processes. We further show that release from organic matter stored in deep deposits of Yedoma regions crucially affects our simulated circumpolar CH4 fluxes. The additional warming through the release from newly thawed permafrost carbon proved only slightly dependent on the pathway of anthropogenic emission and amounts to about 0.03–0.14 °C (68% ranges) by end of the century. The warming increased further in the 22nd and 23rd century and was most pronounced under the RCP6.0 scenario, adding 0.16 to 0.39 °C (68% range) to simulated global mean surface air temperatures in the year 2300.
format Article in Journal/Newspaper
author Schneider Von Deimling, T.
Grosse, G.
Strauss, J.
Schirrmeister, L.
Morgenstern, A.
Schaphoff, S.
Meinshausen, M.
Boike, J.
author_facet Schneider Von Deimling, T.
Grosse, G.
Strauss, J.
Schirrmeister, L.
Morgenstern, A.
Schaphoff, S.
Meinshausen, M.
Boike, J.
author_sort Schneider Von Deimling, T.
title Observation-based modelling of permafrost carbon fluxes with accounting for deep carbon deposits and thermokarst activity
title_short Observation-based modelling of permafrost carbon fluxes with accounting for deep carbon deposits and thermokarst activity
title_full Observation-based modelling of permafrost carbon fluxes with accounting for deep carbon deposits and thermokarst activity
title_fullStr Observation-based modelling of permafrost carbon fluxes with accounting for deep carbon deposits and thermokarst activity
title_full_unstemmed Observation-based modelling of permafrost carbon fluxes with accounting for deep carbon deposits and thermokarst activity
title_sort observation-based modelling of permafrost carbon fluxes with accounting for deep carbon deposits and thermokarst activity
publisher München : European Geopyhsical Union
publishDate 2015
url https://dx.doi.org/10.34657/1134
https://oa.tib.eu/renate/handle/123456789/565
genre permafrost
Thermokarst
genre_facet permafrost
Thermokarst
op_rights Creative Commons Attribution 3.0 Unported
CC BY 3.0 Unported
https://creativecommons.org/licenses/by/3.0/legalcode
cc-by-3.0
op_rightsnorm CC-BY
op_doi https://doi.org/10.34657/1134
_version_ 1766163893897396224

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