Investigating the thermal state of permafrost with Bayesian inverse modeling of heat transfer

Long-term measurements of permafrost temperatures do not provide a complete picture of the Arctic subsurface thermal regime. Regions with warmer permafrost often show little to no long-term change in ground temperature due to the uptake and release of latent heat during freezing and thawing. Thus, r...

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Published in:The Cryosphere
Main Authors: Groenke, Brian, Langer, Moritz, Nitzbon, Jan, Westermann, Sebastian, Gallego, Guillermo, Boike, Julia
Format: Article in Journal/Newspaper
Language:English
Published: 2023
Subjects:
Active layer thickness
Ice
lena river
Ny Ålesund
Ny-Ålesund
permafrost
Svalbard
The Cryosphere
Online Access:http://hdl.handle.net/10852/109523
https://doi.org/10.5194/tc-17-3505-2023
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spelling ftoslouniv:oai:www.duo.uio.no:10852/109523 2024-09-15T17:34:50+00:00 Investigating the thermal state of permafrost with Bayesian inverse modeling of heat transfer ENEngelskEnglishInvestigating the thermal state of permafrost with Bayesian inverse modeling of heat transfer Groenke, Brian Langer, Moritz Nitzbon, Jan Westermann, Sebastian Gallego, Guillermo Boike, Julia 2023-11-07T18:45:34Z http://hdl.handle.net/10852/109523 https://doi.org/10.5194/tc-17-3505-2023 EN eng Groenke, Brian Langer, Moritz Nitzbon, Jan Westermann, Sebastian Gallego, Guillermo Boike, Julia . Investigating the thermal state of permafrost with Bayesian inverse modeling of heat transfer. The Cryosphere. 2023, 17(8), 3505-3533 http://hdl.handle.net/10852/109523 2193536 info:ofi/fmt:kev:mtx:ctx&ctx_ver=Z39.88-2004&rft_val_fmt=info:ofi/fmt:kev:mtx:journal&rft.jtitle=The Cryosphere&rft.volume=17&rft.spage=3505&rft.date=2023 The Cryosphere 17 8 3505 3533 https://doi.org/10.5194/tc-17-3505-2023 Attribution 4.0 International https://creativecommons.org/licenses/by/4.0/ 1994-0416 Journal article Tidsskriftartikkel Peer reviewed PublishedVersion 2023 ftoslouniv https://doi.org/10.5194/tc-17-3505-2023 2024-08-05T14:09:29Z Long-term measurements of permafrost temperatures do not provide a complete picture of the Arctic subsurface thermal regime. Regions with warmer permafrost often show little to no long-term change in ground temperature due to the uptake and release of latent heat during freezing and thawing. Thus, regions where the least warming is observed may also be the most vulnerable to permafrost degradation. Since direct measurements of ice and liquid water contents in the permafrost layer are not widely available, thermal modeling of the subsurface plays a crucial role in understanding how permafrost responds to changes in the local energy balance. In this work, we first analyze trends in observed air and permafrost temperatures at four sites within the continuous permafrost zone, where we find substantial variation in the apparent relationship between long-term changes in permafrost temperatures (0.02–0.16 K yr−1) and air temperature (0.09–0.11 K yr−1). We then apply recently developed Bayesian inversion methods to link observed changes in borehole temperatures to unobserved changes in latent heat and active layer thickness using a transient model of heat conduction with phase change. Our results suggest that the degree to which recent warming trends correlate with permafrost thaw depends strongly on both soil freezing characteristics and historical climatology. At the warmest site, a 9 m borehole near Ny-Ålesund, Svalbard, modeled active layer thickness increases by an average of 13 ± 1 cm K−1 rise in mean annual ground temperature. In stark contrast, modeled rates of thaw at one of the colder sites, a borehole on Samoylov Island in the Lena River delta, appear far less sensitive to temperature change, with a negligible effect of 1 ± 1 cm K−1. Although our study is limited to just four sites, the results urge caution in the interpretation and comparison of warming trends in Arctic boreholes, indicating significant uncertainty in their implications for the current and future thermal state of permafrost. Article in Journal/Newspaper Active layer thickness Ice lena river Ny Ålesund Ny-Ålesund permafrost Svalbard The Cryosphere Universitet i Oslo: Digitale utgivelser ved UiO (DUO) The Cryosphere 17 8 3505 3533
institution Open Polar
collection Universitet i Oslo: Digitale utgivelser ved UiO (DUO)
op_collection_id ftoslouniv
language English
description Long-term measurements of permafrost temperatures do not provide a complete picture of the Arctic subsurface thermal regime. Regions with warmer permafrost often show little to no long-term change in ground temperature due to the uptake and release of latent heat during freezing and thawing. Thus, regions where the least warming is observed may also be the most vulnerable to permafrost degradation. Since direct measurements of ice and liquid water contents in the permafrost layer are not widely available, thermal modeling of the subsurface plays a crucial role in understanding how permafrost responds to changes in the local energy balance. In this work, we first analyze trends in observed air and permafrost temperatures at four sites within the continuous permafrost zone, where we find substantial variation in the apparent relationship between long-term changes in permafrost temperatures (0.02–0.16 K yr−1) and air temperature (0.09–0.11 K yr−1). We then apply recently developed Bayesian inversion methods to link observed changes in borehole temperatures to unobserved changes in latent heat and active layer thickness using a transient model of heat conduction with phase change. Our results suggest that the degree to which recent warming trends correlate with permafrost thaw depends strongly on both soil freezing characteristics and historical climatology. At the warmest site, a 9 m borehole near Ny-Ålesund, Svalbard, modeled active layer thickness increases by an average of 13 ± 1 cm K−1 rise in mean annual ground temperature. In stark contrast, modeled rates of thaw at one of the colder sites, a borehole on Samoylov Island in the Lena River delta, appear far less sensitive to temperature change, with a negligible effect of 1 ± 1 cm K−1. Although our study is limited to just four sites, the results urge caution in the interpretation and comparison of warming trends in Arctic boreholes, indicating significant uncertainty in their implications for the current and future thermal state of permafrost.
format Article in Journal/Newspaper
author Groenke, Brian
Langer, Moritz
Nitzbon, Jan
Westermann, Sebastian
Gallego, Guillermo
Boike, Julia
spellingShingle Groenke, Brian
Langer, Moritz
Nitzbon, Jan
Westermann, Sebastian
Gallego, Guillermo
Boike, Julia
Investigating the thermal state of permafrost with Bayesian inverse modeling of heat transfer
author_facet Groenke, Brian
Langer, Moritz
Nitzbon, Jan
Westermann, Sebastian
Gallego, Guillermo
Boike, Julia
author_sort Groenke, Brian
title Investigating the thermal state of permafrost with Bayesian inverse modeling of heat transfer
title_short Investigating the thermal state of permafrost with Bayesian inverse modeling of heat transfer
title_full Investigating the thermal state of permafrost with Bayesian inverse modeling of heat transfer
title_fullStr Investigating the thermal state of permafrost with Bayesian inverse modeling of heat transfer
title_full_unstemmed Investigating the thermal state of permafrost with Bayesian inverse modeling of heat transfer
title_sort investigating the thermal state of permafrost with bayesian inverse modeling of heat transfer
publishDate 2023
url http://hdl.handle.net/10852/109523
https://doi.org/10.5194/tc-17-3505-2023
genre Active layer thickness
Ice
lena river
Ny Ålesund
Ny-Ålesund
permafrost
Svalbard
The Cryosphere
genre_facet Active layer thickness
Ice
lena river
Ny Ålesund
Ny-Ålesund
permafrost
Svalbard
The Cryosphere
op_source 1994-0416
op_relation Groenke, Brian Langer, Moritz Nitzbon, Jan Westermann, Sebastian Gallego, Guillermo Boike, Julia . Investigating the thermal state of permafrost with Bayesian inverse modeling of heat transfer. The Cryosphere. 2023, 17(8), 3505-3533
http://hdl.handle.net/10852/109523
2193536
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The Cryosphere
17
8
3505
3533
https://doi.org/10.5194/tc-17-3505-2023
op_rights Attribution 4.0 International
https://creativecommons.org/licenses/by/4.0/
op_doi https://doi.org/10.5194/tc-17-3505-2023
container_title The Cryosphere
container_volume 17
container_issue 8
container_start_page 3505
op_container_end_page 3533
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