Permafrost modelling over different scales in arctic and high-mountain environments

Permafrost is present in several parts of Norway and contributes to binding mountain rock walls together, as well as storing potential greenhouse gasses as organic carbon in mires. Global climate changes influence the ground temperatures, and as a result the permafrost will thaw in some areas. This...

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Published in:Permafrost and Periglacial Processes
Main Author: Gisnås, Kjersti
Format: Doctoral or Postdoctoral Thesis
Language:English
Published: 2016
Subjects:
Arctic
Gisnås
Norway
Climate change
permafrost
Permafrost and Periglacial Processes
The Cryosphere
Online Access:http://hdl.handle.net/10852/51037
http://urn.nb.no/URN:NBN:no-54520
id ftoslouniv:oai:www.duo.uio.no:10852/51037
record_format openpolar
institution Open Polar
collection Universitet i Oslo: Digitale utgivelser ved UiO (DUO)
op_collection_id ftoslouniv
language English
description Permafrost is present in several parts of Norway and contributes to binding mountain rock walls together, as well as storing potential greenhouse gasses as organic carbon in mires. Global climate changes influence the ground temperatures, and as a result the permafrost will thaw in some areas. This thesis provides new insight in the decisive role of the snow distribution in high mountain areas for correct estimates of ground temperatures in climate models. Large parts of the high mountain areas and the mires in Scandinavia are frozen all year around. This phenomenon is called permafrost. Permafrost acts as a glue in mountain areas, and if the permafrost warms or thaws entirely, resulting destabilization of the rock walls could threaten both infrastructure and lives. In permafrost areas with a high organic content, thawing permafrost will release the carbon storage in the ground as greenhouse gasses, and act as a feedback mechanism to the global climate change. It is therefore crucial to understand how existing permafrost will react to the future changes in the climate. In order to know how the permafrost in mountains and lowland areas will respond to the future climate, precise and detailed models for ground temperatures are required. The low thermal conductivity of snow cover makes it an efficient insulator to cold winter temperatures, and it therefore has profound implications for the thermal regime of the ground. Because of drifting snow, snow depths can be highly variable – from bare-blow ridges to deep troughs, sometimes only meters apart. Climate- and weather models traditionally operate on coarse resolutions, and use snow depths averaged over lager areas (> 1 km). In this thesis Gisnås demonstrates the errors introduced into permafrost models by this simplified representation of snow. Particularly bare-blown areas, where we find the coldest permafrost, are not well represented in current models. Statistical methods for representation of small-scale variation in snow depths in regional weather- and permafrost models have therefore been developed in this study. These methods highly improve the representation of the ground temperatures as well as the response in ground temperatures to climate changes in permafrost models. The improved permafrost model is implemented for Scandinavia, and a new map of permafrost in this region is produced. The map provides new knowledge and a much higher level of detail of the total distribution of permafrost, and gives new insight in which areas that are vulnerable to future climate changes.
format Doctoral or Postdoctoral Thesis
author Gisnås, Kjersti
spellingShingle Gisnås, Kjersti
Permafrost modelling over different scales in arctic and high-mountain environments
author_facet Gisnås, Kjersti
author_sort Gisnås, Kjersti
title Permafrost modelling over different scales in arctic and high-mountain environments
title_short Permafrost modelling over different scales in arctic and high-mountain environments
title_full Permafrost modelling over different scales in arctic and high-mountain environments
title_fullStr Permafrost modelling over different scales in arctic and high-mountain environments
title_full_unstemmed Permafrost modelling over different scales in arctic and high-mountain environments
title_sort permafrost modelling over different scales in arctic and high-mountain environments
publishDate 2016
url http://hdl.handle.net/10852/51037
http://urn.nb.no/URN:NBN:no-54520
long_lat ENVELOPE(9.933,9.933,62.700,62.700)
geographic Arctic
Gisnås
Norway
geographic_facet Arctic
Gisnås
Norway
genre Arctic
Climate change
permafrost
Permafrost and Periglacial Processes
The Cryosphere
genre_facet Arctic
Climate change
permafrost
Permafrost and Periglacial Processes
The Cryosphere
op_relation Paper I: Gisnås, K., B. Etzelmuller, H. Farbrot, T. V. Schuler, and S. Westermann. 2013. CryoGRID 1.0: Permafrost distribution in Norway estimated by a spatial numerical model. Permafrost and Periglacial Processes. The paper is not available in DUO due to publisher restrictions. The published version is available at: http://dx.doi.org/10.1002/ppp.1765
Paper II: Gisnås, K., Westermann, S., Schuler, T. V., Litherland, T., Isaksen, K., Boike, J., and Etzelmüller, B. 2014. A statistical approach to represent small-scale variability of permafrost temperatures due to snow cover. The Cryosphere, 8, 2063-2074. The paper is available in DUO: http://urn.nb.no/URN:NBN:no-54521
Paper III: Gisnås K, S. Westermann, T.V. Schuler, K. Melvold and B. Etzelmüller. Small-scale variation of snow in a regional permafrost model. The Cryosphere Discuss., 9, 6661-6696, 2015. The paper is available in DUO: http://urn.nb.no/URN:NBN:no-54522
Paper IV: Aas, K.S., K. Gisnås, S. Westermann, T. Berntsen. A tiling approach to represent sub-grid snow variability in coupled land-surface – atmosphere models. Submitted to Journal of Hydrometeorology, January 2016. To be published. The paper is not available in DUO awaiting publishing.
Paper V: Gisnås K., B. Etzelmüller, C. Lussana, J. Hjort, A.B.K. Sannel, K. Isaksen, S. Westermann, P. Kuhry, H.H. Christiansen, A. Frampton, A. Frampton and J. Åkerman: A new permafrost map for the Scandinavian Peninsula. Submitted to Permafrost and Periglacial Processes, February 2016. To be published. The paper is not available in DUO awaiting publishing.
http://dx.doi.org/10.1002/ppp.1765
http://urn.nb.no/URN:NBN:no-54521
http://urn.nb.no/URN:NBN:no-54522
http://urn.nb.no/URN:NBN:no-54520
http://hdl.handle.net/10852/51037
URN:NBN:no-54520
Fulltext https://www.duo.uio.no/bitstream/handle/10852/51037/1/Gisnas-thesis-DUO.pdf
op_doi https://doi.org/10.1002/ppp.1765
container_title Permafrost and Periglacial Processes
container_volume 24
container_issue 1
container_start_page 2
op_container_end_page 19
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spelling ftoslouniv:oai:www.duo.uio.no:10852/51037 2023-05-15T15:19:20+02:00 Permafrost modelling over different scales in arctic and high-mountain environments Gisnås, Kjersti 2016 http://hdl.handle.net/10852/51037 http://urn.nb.no/URN:NBN:no-54520 en eng Paper I: Gisnås, K., B. Etzelmuller, H. Farbrot, T. V. Schuler, and S. Westermann. 2013. CryoGRID 1.0: Permafrost distribution in Norway estimated by a spatial numerical model. Permafrost and Periglacial Processes. The paper is not available in DUO due to publisher restrictions. The published version is available at: http://dx.doi.org/10.1002/ppp.1765 Paper II: Gisnås, K., Westermann, S., Schuler, T. V., Litherland, T., Isaksen, K., Boike, J., and Etzelmüller, B. 2014. A statistical approach to represent small-scale variability of permafrost temperatures due to snow cover. The Cryosphere, 8, 2063-2074. The paper is available in DUO: http://urn.nb.no/URN:NBN:no-54521 Paper III: Gisnås K, S. Westermann, T.V. Schuler, K. Melvold and B. Etzelmüller. Small-scale variation of snow in a regional permafrost model. The Cryosphere Discuss., 9, 6661-6696, 2015. The paper is available in DUO: http://urn.nb.no/URN:NBN:no-54522 Paper IV: Aas, K.S., K. Gisnås, S. Westermann, T. Berntsen. A tiling approach to represent sub-grid snow variability in coupled land-surface – atmosphere models. Submitted to Journal of Hydrometeorology, January 2016. To be published. The paper is not available in DUO awaiting publishing. Paper V: Gisnås K., B. Etzelmüller, C. Lussana, J. Hjort, A.B.K. Sannel, K. Isaksen, S. Westermann, P. Kuhry, H.H. Christiansen, A. Frampton, A. Frampton and J. Åkerman: A new permafrost map for the Scandinavian Peninsula. Submitted to Permafrost and Periglacial Processes, February 2016. To be published. The paper is not available in DUO awaiting publishing. http://dx.doi.org/10.1002/ppp.1765 http://urn.nb.no/URN:NBN:no-54521 http://urn.nb.no/URN:NBN:no-54522 http://urn.nb.no/URN:NBN:no-54520 http://hdl.handle.net/10852/51037 URN:NBN:no-54520 Fulltext https://www.duo.uio.no/bitstream/handle/10852/51037/1/Gisnas-thesis-DUO.pdf Doctoral thesis Doktoravhandling 2016 ftoslouniv https://doi.org/10.1002/ppp.1765 2020-06-21T08:49:55Z Permafrost is present in several parts of Norway and contributes to binding mountain rock walls together, as well as storing potential greenhouse gasses as organic carbon in mires. Global climate changes influence the ground temperatures, and as a result the permafrost will thaw in some areas. This thesis provides new insight in the decisive role of the snow distribution in high mountain areas for correct estimates of ground temperatures in climate models. Large parts of the high mountain areas and the mires in Scandinavia are frozen all year around. This phenomenon is called permafrost. Permafrost acts as a glue in mountain areas, and if the permafrost warms or thaws entirely, resulting destabilization of the rock walls could threaten both infrastructure and lives. In permafrost areas with a high organic content, thawing permafrost will release the carbon storage in the ground as greenhouse gasses, and act as a feedback mechanism to the global climate change. It is therefore crucial to understand how existing permafrost will react to the future changes in the climate. In order to know how the permafrost in mountains and lowland areas will respond to the future climate, precise and detailed models for ground temperatures are required. The low thermal conductivity of snow cover makes it an efficient insulator to cold winter temperatures, and it therefore has profound implications for the thermal regime of the ground. Because of drifting snow, snow depths can be highly variable – from bare-blow ridges to deep troughs, sometimes only meters apart. Climate- and weather models traditionally operate on coarse resolutions, and use snow depths averaged over lager areas (> 1 km). In this thesis Gisnås demonstrates the errors introduced into permafrost models by this simplified representation of snow. Particularly bare-blown areas, where we find the coldest permafrost, are not well represented in current models. Statistical methods for representation of small-scale variation in snow depths in regional weather- and permafrost models have therefore been developed in this study. These methods highly improve the representation of the ground temperatures as well as the response in ground temperatures to climate changes in permafrost models. The improved permafrost model is implemented for Scandinavia, and a new map of permafrost in this region is produced. The map provides new knowledge and a much higher level of detail of the total distribution of permafrost, and gives new insight in which areas that are vulnerable to future climate changes. Doctoral or Postdoctoral Thesis Arctic Climate change permafrost Permafrost and Periglacial Processes The Cryosphere Universitet i Oslo: Digitale utgivelser ved UiO (DUO) Arctic Gisnås ENVELOPE(9.933,9.933,62.700,62.700) Norway Permafrost and Periglacial Processes 24 1 2 19

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