Response of methane emissions from wetlands to the Last Glacial Maximum and an idealized Dansgaard–Oeschger climate event: insights from two models of different complexity

The role of different sources and sinks of CH4 in changes in atmospheric methane ([CH4]) concentration during the last 100 000 yr is still not fully understood. In particular, the magnitude of the change in wetland CH4 emissions at the Last Glacial Maximum (LGM) relative to the pre-industrial period...

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Published in:Climate of the Past
Main Authors: Ringeval, Bruno, Hopcroft, P. O., Valdes, P. J., Ciais, P., Ramstein, G., Dolman, A. J., Kageyama, M.
Format: Article in Journal/Newspaper
Language:English
Published: 2013
Subjects:
atmosphère
méthane
inversion atmosphérique
variabilité climatique
zone humide
Ice
ice core
permafrost
Online Access:http://prodinra.inra.fr/ft/25E7F760-3457-466E-BDD5-A68EFCFA66AD
http://prodinra.inra.fr/record/356792
https://doi.org/10.5194/cp-9-149-2013
id ftinraparis:oai:prodinra.inra.fr:356792
record_format openpolar
spelling ftinraparis:oai:prodinra.inra.fr:356792 2023-05-15T16:37:51+02:00 Response of methane emissions from wetlands to the Last Glacial Maximum and an idealized Dansgaard–Oeschger climate event: insights from two models of different complexity Ringeval, Bruno Hopcroft, P. O. Valdes, P. J. Ciais, P. Ramstein, G. Dolman, A. J. Kageyama, M. 2013 application/pdf http://prodinra.inra.fr/ft/25E7F760-3457-466E-BDD5-A68EFCFA66AD http://prodinra.inra.fr/record/356792 https://doi.org/10.5194/cp-9-149-2013 eng eng http://creativecommons.org/licenses/by-nd-nc/1.0/ CC-BY-ND-NC Climate of the past 1 (9), 149-171. (2013) atmosphère méthane inversion atmosphérique variabilité climatique zone humide ARTICLE 2013 ftinraparis https://doi.org/10.5194/cp-9-149-2013 2017-04-18T22:24:17Z The role of different sources and sinks of CH4 in changes in atmospheric methane ([CH4]) concentration during the last 100 000 yr is still not fully understood. In particular, the magnitude of the change in wetland CH4 emissions at the Last Glacial Maximum (LGM) relative to the pre-industrial period (PI), as well as during abrupt climatic warming or Dansgaard–Oeschger (D–O) events of the last glacial period, is largely unconstrained. In the present study, we aim to understand the uncertainties related to the parameterization of the wetland CH4 emission models relevant to these time periods by using two wetland models of different complexity (SDGVM and ORCHIDEE). These models have been forced by identical climate fields from low-resolution coupled atmosphere–ocean general circulation model (FAMOUS) simulations of these time periods. Both emission models simulate a large decrease in emissions during LGM in comparison to PI consistent with ice core observations and previous modelling studies. The global reduction is much larger in ORCHIDEE than in SDGVM (respectively −67 and −46%), and whilst the differences can be partially explained by different model sensitivities to temperature, the major reason for spatial differences between the models is the inclusion of freezing of soil water in ORCHIDEE and the resultant impact on methanogenesis substrate availability in boreal regions. Besides, a sensitivity test performed with ORCHIDEE in which the methanogenesis substrate sensitivity to the precipitations is modified to be more realistic gives a LGM reduction of −36%. The range of the global LGM decrease is still prone to uncertainty, and here we underline its sensitivity to different process parameterizations. Over the course of an idealized D–O warming, the magnitude of the change in wetland CH4 emissions simulated by the two models at global scale is very similar at around 15 Tg yr−1, but this is only around 25% of the ice-core measured changes in [CH4]. The two models do show regional differences in emission sensitivity to climate with much larger magnitudes of northern and southern tropical anomalies in ORCHIDEE. However, the simulated northern and southern tropical anomalies partially compensate each other in both models limiting the net flux change. Future work may need to consider the inclusion of more detailed wetland processes (e.g. linked to permafrost or tropical floodplains), other non-wetland CH4 sources or different patterns of D–O climate change in order to be able to reconcile emission estimates with the ice-core data for rapid CH4 events. Article in Journal/Newspaper Ice ice core permafrost Institut National de la Recherche Agronomique: ProdINRA Climate of the Past 9 1 149 171
institution Open Polar
collection Institut National de la Recherche Agronomique: ProdINRA
op_collection_id ftinraparis
language English
topic atmosphère
méthane
inversion atmosphérique
variabilité climatique
zone humide
spellingShingle atmosphère
méthane
inversion atmosphérique
variabilité climatique
zone humide
Ringeval, Bruno
Hopcroft, P. O.
Valdes, P. J.
Ciais, P.
Ramstein, G.
Dolman, A. J.
Kageyama, M.
Response of methane emissions from wetlands to the Last Glacial Maximum and an idealized Dansgaard–Oeschger climate event: insights from two models of different complexity
topic_facet atmosphère
méthane
inversion atmosphérique
variabilité climatique
zone humide
description The role of different sources and sinks of CH4 in changes in atmospheric methane ([CH4]) concentration during the last 100 000 yr is still not fully understood. In particular, the magnitude of the change in wetland CH4 emissions at the Last Glacial Maximum (LGM) relative to the pre-industrial period (PI), as well as during abrupt climatic warming or Dansgaard–Oeschger (D–O) events of the last glacial period, is largely unconstrained. In the present study, we aim to understand the uncertainties related to the parameterization of the wetland CH4 emission models relevant to these time periods by using two wetland models of different complexity (SDGVM and ORCHIDEE). These models have been forced by identical climate fields from low-resolution coupled atmosphere–ocean general circulation model (FAMOUS) simulations of these time periods. Both emission models simulate a large decrease in emissions during LGM in comparison to PI consistent with ice core observations and previous modelling studies. The global reduction is much larger in ORCHIDEE than in SDGVM (respectively −67 and −46%), and whilst the differences can be partially explained by different model sensitivities to temperature, the major reason for spatial differences between the models is the inclusion of freezing of soil water in ORCHIDEE and the resultant impact on methanogenesis substrate availability in boreal regions. Besides, a sensitivity test performed with ORCHIDEE in which the methanogenesis substrate sensitivity to the precipitations is modified to be more realistic gives a LGM reduction of −36%. The range of the global LGM decrease is still prone to uncertainty, and here we underline its sensitivity to different process parameterizations. Over the course of an idealized D–O warming, the magnitude of the change in wetland CH4 emissions simulated by the two models at global scale is very similar at around 15 Tg yr−1, but this is only around 25% of the ice-core measured changes in [CH4]. The two models do show regional differences in emission sensitivity to climate with much larger magnitudes of northern and southern tropical anomalies in ORCHIDEE. However, the simulated northern and southern tropical anomalies partially compensate each other in both models limiting the net flux change. Future work may need to consider the inclusion of more detailed wetland processes (e.g. linked to permafrost or tropical floodplains), other non-wetland CH4 sources or different patterns of D–O climate change in order to be able to reconcile emission estimates with the ice-core data for rapid CH4 events.
format Article in Journal/Newspaper
author Ringeval, Bruno
Hopcroft, P. O.
Valdes, P. J.
Ciais, P.
Ramstein, G.
Dolman, A. J.
Kageyama, M.
author_facet Ringeval, Bruno
Hopcroft, P. O.
Valdes, P. J.
Ciais, P.
Ramstein, G.
Dolman, A. J.
Kageyama, M.
author_sort Ringeval, Bruno
title Response of methane emissions from wetlands to the Last Glacial Maximum and an idealized Dansgaard–Oeschger climate event: insights from two models of different complexity
title_short Response of methane emissions from wetlands to the Last Glacial Maximum and an idealized Dansgaard–Oeschger climate event: insights from two models of different complexity
title_full Response of methane emissions from wetlands to the Last Glacial Maximum and an idealized Dansgaard–Oeschger climate event: insights from two models of different complexity
title_fullStr Response of methane emissions from wetlands to the Last Glacial Maximum and an idealized Dansgaard–Oeschger climate event: insights from two models of different complexity
title_full_unstemmed Response of methane emissions from wetlands to the Last Glacial Maximum and an idealized Dansgaard–Oeschger climate event: insights from two models of different complexity
title_sort response of methane emissions from wetlands to the last glacial maximum and an idealized dansgaard–oeschger climate event: insights from two models of different complexity
publishDate 2013
url http://prodinra.inra.fr/ft/25E7F760-3457-466E-BDD5-A68EFCFA66AD
http://prodinra.inra.fr/record/356792
https://doi.org/10.5194/cp-9-149-2013
genre Ice
ice core
permafrost
genre_facet Ice
ice core
permafrost
op_source Climate of the past 1 (9), 149-171. (2013)
op_rights http://creativecommons.org/licenses/by-nd-nc/1.0/
op_rightsnorm CC-BY-ND-NC
op_doi https://doi.org/10.5194/cp-9-149-2013
container_title Climate of the Past
container_volume 9
container_issue 1
container_start_page 149
op_container_end_page 171
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