Present and LGM permafrost from climate simulations: contribution of statistical downscaling

We quantify the agreement between permafrost distributions from PMIP2 (Paleoclimate Modeling Intercomparison Project) climate models and permafrost data. We evaluate the ability of several climate models to represent permafrost and assess the variability between their results. Studying a heterogeneo...

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Published in:Climate of the Past
Main Authors: Levavasseur, G., Vrac, M., Roche, D. M., Paillard, D., Martin, A., Vandenberghe, J.
Format: Text
Language:English
Published: 2018
Subjects:
Gam
permafrost
Online Access:https://doi.org/10.5194/cp-7-1225-2011
https://cp.copernicus.org/articles/7/1225/2011/
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spelling ftcopernicus:oai:publications.copernicus.org:cp11414 2023-05-15T17:55:22+02:00 Present and LGM permafrost from climate simulations: contribution of statistical downscaling Levavasseur, G. Vrac, M. Roche, D. M. Paillard, D. Martin, A. Vandenberghe, J. 2018-09-27 application/pdf https://doi.org/10.5194/cp-7-1225-2011 https://cp.copernicus.org/articles/7/1225/2011/ eng eng doi:10.5194/cp-7-1225-2011 https://cp.copernicus.org/articles/7/1225/2011/ eISSN: 1814-9332 Text 2018 ftcopernicus https://doi.org/10.5194/cp-7-1225-2011 2020-07-20T16:25:58Z We quantify the agreement between permafrost distributions from PMIP2 (Paleoclimate Modeling Intercomparison Project) climate models and permafrost data. We evaluate the ability of several climate models to represent permafrost and assess the variability between their results. Studying a heterogeneous variable such as permafrost implies conducting analysis at a smaller spatial scale compared with climate models resolution. Our approach consists of applying statistical downscaling methods (SDMs) on large- or regional-scale atmospheric variables provided by climate models, leading to local-scale permafrost modelling. Among the SDMs, we first choose a transfer function approach based on Generalized Additive Models (GAMs) to produce high-resolution climatology of air temperature at the surface. Then we define permafrost distribution over Eurasia by air temperature conditions. In a first validation step on present climate (CTRL period), this method shows some limitations with non-systematic improvements in comparison with the large-scale fields. So, we develop an alternative method of statistical downscaling based on a Multinomial Logistic GAM (ML-GAM), which directly predicts the occurrence probabilities of local-scale permafrost. The obtained permafrost distributions appear in a better agreement with CTRL data. In average for the nine PMIP2 models, we measure a global agreement with CTRL permafrost data that is better when using ML-GAM than when applying the GAM method with air temperature conditions. In both cases, the provided local information reduces the variability between climate models results. This also confirms that a simple relationship between permafrost and the air temperature only is not always sufficient to represent local-scale permafrost. Finally, we apply each method on a very different climate, the Last Glacial Maximum (LGM) time period, in order to quantify the ability of climate models to represent LGM permafrost. The prediction of the SDMs (GAM and ML-GAM) is not significantly in better agreement with LGM permafrost data than large-scale fields. At the LGM, both methods do not reduce the variability between climate models results. We show that LGM permafrost distribution from climate models strongly depends on large-scale air temperature at the surface. LGM simulations from climate models lead to larger differences with LGM data than in the CTRL period. These differences reduce the contribution of downscaling. Text permafrost Copernicus Publications: E-Journals Gam ENVELOPE(-57.955,-57.955,-61.923,-61.923) Climate of the Past 7 4 1225 1246
institution Open Polar
collection Copernicus Publications: E-Journals
op_collection_id ftcopernicus
language English
description We quantify the agreement between permafrost distributions from PMIP2 (Paleoclimate Modeling Intercomparison Project) climate models and permafrost data. We evaluate the ability of several climate models to represent permafrost and assess the variability between their results. Studying a heterogeneous variable such as permafrost implies conducting analysis at a smaller spatial scale compared with climate models resolution. Our approach consists of applying statistical downscaling methods (SDMs) on large- or regional-scale atmospheric variables provided by climate models, leading to local-scale permafrost modelling. Among the SDMs, we first choose a transfer function approach based on Generalized Additive Models (GAMs) to produce high-resolution climatology of air temperature at the surface. Then we define permafrost distribution over Eurasia by air temperature conditions. In a first validation step on present climate (CTRL period), this method shows some limitations with non-systematic improvements in comparison with the large-scale fields. So, we develop an alternative method of statistical downscaling based on a Multinomial Logistic GAM (ML-GAM), which directly predicts the occurrence probabilities of local-scale permafrost. The obtained permafrost distributions appear in a better agreement with CTRL data. In average for the nine PMIP2 models, we measure a global agreement with CTRL permafrost data that is better when using ML-GAM than when applying the GAM method with air temperature conditions. In both cases, the provided local information reduces the variability between climate models results. This also confirms that a simple relationship between permafrost and the air temperature only is not always sufficient to represent local-scale permafrost. Finally, we apply each method on a very different climate, the Last Glacial Maximum (LGM) time period, in order to quantify the ability of climate models to represent LGM permafrost. The prediction of the SDMs (GAM and ML-GAM) is not significantly in better agreement with LGM permafrost data than large-scale fields. At the LGM, both methods do not reduce the variability between climate models results. We show that LGM permafrost distribution from climate models strongly depends on large-scale air temperature at the surface. LGM simulations from climate models lead to larger differences with LGM data than in the CTRL period. These differences reduce the contribution of downscaling.
format Text
author Levavasseur, G.
Vrac, M.
Roche, D. M.
Paillard, D.
Martin, A.
Vandenberghe, J.
spellingShingle Levavasseur, G.
Vrac, M.
Roche, D. M.
Paillard, D.
Martin, A.
Vandenberghe, J.
Present and LGM permafrost from climate simulations: contribution of statistical downscaling
author_facet Levavasseur, G.
Vrac, M.
Roche, D. M.
Paillard, D.
Martin, A.
Vandenberghe, J.
author_sort Levavasseur, G.
title Present and LGM permafrost from climate simulations: contribution of statistical downscaling
title_short Present and LGM permafrost from climate simulations: contribution of statistical downscaling
title_full Present and LGM permafrost from climate simulations: contribution of statistical downscaling
title_fullStr Present and LGM permafrost from climate simulations: contribution of statistical downscaling
title_full_unstemmed Present and LGM permafrost from climate simulations: contribution of statistical downscaling
title_sort present and lgm permafrost from climate simulations: contribution of statistical downscaling
publishDate 2018
url https://doi.org/10.5194/cp-7-1225-2011
https://cp.copernicus.org/articles/7/1225/2011/
long_lat ENVELOPE(-57.955,-57.955,-61.923,-61.923)
geographic Gam
geographic_facet Gam
genre permafrost
genre_facet permafrost
op_source eISSN: 1814-9332
op_relation doi:10.5194/cp-7-1225-2011
https://cp.copernicus.org/articles/7/1225/2011/
op_doi https://doi.org/10.5194/cp-7-1225-2011
container_title Climate of the Past
container_volume 7
container_issue 4
container_start_page 1225
op_container_end_page 1246
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