Simulated high-latitude soil thermal dynamics during the past 4 decades

abstract: Soil temperature (T[subscript s]) change is a key indicator of the dynamics of permafrost. On seasonal and interannual timescales, the variability of T[subscript s] determines the active-layer depth, which regulates hydrological soil properties and biogeochemical processes. On the multi-de...

Full description

Bibliographic Details
Published in:The Cryosphere
Other Authors: Peng, S. (Author), Ciais, P. (Author), Krinner, G. (Author), Wang, T. (Author), Gouttevin, I. (Author), McGuire, A. D. (Author), Lawrence, D. (Author), Burke, E. (Author), Chen, X. (Author), Decharme, B. (Author), Koven, C. (Author), MacDougall, A. (Author), Rinke, A. (Author), Saito, K. (Author), Zhang, W. (Author), Alkama, R. (Author), Bohn, Theodore (ASU author), Delire, C. (Author), Hajima, T. (Author), Ji, D. (Author), Lettenmaier, D. P. (Author), Miller, P. A. (Author), Moore, J. C. (Author), Smith, B. (Author), Sueyoshi, T. (Author), College of Liberal Arts and Sciences, School of Earth and Space Exploration, Julie Ann Wrigley Global Institute of Sustainability
Format: Text
Language:English
Published: 2016
Subjects:
Active layer thickness
permafrost
The Cryosphere
Online Access:https://doi.org/10.5194/tc-10-179-2016
http://hdl.handle.net/2286/R.I.44929
id ftarizonastateun:item:44929
record_format openpolar
institution Open Polar
collection Arizona State University: ASU Digital Repository
op_collection_id ftarizonastateun
language English
description abstract: Soil temperature (T[subscript s]) change is a key indicator of the dynamics of permafrost. On seasonal and interannual timescales, the variability of T[subscript s] determines the active-layer depth, which regulates hydrological soil properties and biogeochemical processes. On the multi-decadal scale, increasing T[subscript s] not only drives permafrost thaw/retreat but can also trigger and accelerate the decomposition of soil organic carbon. The magnitude of permafrost carbon feedbacks is thus closely linked to the rate of change of soil thermal regimes. In this study, we used nine process-based ecosystem models with permafrost processes, all forced by different observation-based climate forcing during the period 1960–2000, to characterize the warming rate of T[subscript s] in permafrost regions. There is a large spread of T[subscript s] trends at 20 cm depth across the models, with trend values ranging from 0.010 ± 0.003 to 0.031 ± 0.005 °C yr[superscript −1]. Most models show smaller increase in T[subscript s] with increasing depth. Air temperature (Tsub>a) and longwave downward radiation (LWDR) are the main drivers of T[subscript s] trends, but their relative contributions differ amongst the models. Different trends of LWDR used in the forcing of models can explain 61 % of their differences in T[subscript s] trends, while trends of T[subscript a] only explain 5 % of the differences in T[subscript s] trends. Uncertain climate forcing contributes a larger uncertainty in T[subscript s] trends (0.021 ± 0.008 °C yr[superscript −1], mean ± standard deviation) than the uncertainty of model structure (0.012 ± 0.001 °C yr[superscript −1]), diagnosed from the range of response between different models, normalized to the same forcing. In addition, the loss rate of near-surface permafrost area, defined as total area where the maximum seasonal active-layer thickness (ALT) is less than 3 m loss rate, is found to be significantly correlated with the magnitude of the trends of T[subscript s] at 1 m depth across the models (R = −0.85, P = 0.003), but not with the initial total near-surface permafrost area (R = −0.30, P = 0.438). The sensitivity of the total boreal near-surface permafrost area to T[subscript s] at 1 m is estimated to be of −2.80 ± 0.67 million km[superscript 2 ]°C[superscript −1]. Finally, by using two long-term LWDR data sets and relationships between trends of LWDR and T[subscript s] across models, we infer an observation-constrained total boreal near-surface permafrost area decrease comprising between 39 ± 14 × 10[superscript 3] and 75 ± 14 × 10[superscript 3 ]km[superscript 2 ]yr[superscript −1] from 1960 to 2000. This corresponds to 9–18 % degradation of the current permafrost area. This article and any associated published material is distributed under the Creative Commons Attribution 3.0 License. View the article as published at: https://www.the-cryosphere.net/10/179/2016/
author2 Peng, S. (Author)
Ciais, P. (Author)
Krinner, G. (Author)
Wang, T. (Author)
Gouttevin, I. (Author)
McGuire, A. D. (Author)
Lawrence, D. (Author)
Burke, E. (Author)
Chen, X. (Author)
Decharme, B. (Author)
Koven, C. (Author)
MacDougall, A. (Author)
Rinke, A. (Author)
Saito, K. (Author)
Zhang, W. (Author)
Alkama, R. (Author)
Bohn, Theodore (ASU author)
Delire, C. (Author)
Hajima, T. (Author)
Ji, D. (Author)
Lettenmaier, D. P. (Author)
Miller, P. A. (Author)
Moore, J. C. (Author)
Smith, B. (Author)
Sueyoshi, T. (Author)
College of Liberal Arts and Sciences
School of Earth and Space Exploration
Julie Ann Wrigley Global Institute of Sustainability
format Text
title Simulated high-latitude soil thermal dynamics during the past 4 decades
spellingShingle Simulated high-latitude soil thermal dynamics during the past 4 decades
title_short Simulated high-latitude soil thermal dynamics during the past 4 decades
title_full Simulated high-latitude soil thermal dynamics during the past 4 decades
title_fullStr Simulated high-latitude soil thermal dynamics during the past 4 decades
title_full_unstemmed Simulated high-latitude soil thermal dynamics during the past 4 decades
title_sort simulated high-latitude soil thermal dynamics during the past 4 decades
publishDate 2016
url https://doi.org/10.5194/tc-10-179-2016
http://hdl.handle.net/2286/R.I.44929
genre Active layer thickness
permafrost
The Cryosphere
genre_facet Active layer thickness
permafrost
The Cryosphere
op_relation CRYOSPHERE
doi:10.5194/tc-10-179-2016
ISSN: 1994-0416
ISSN: 1994-0424
Peng, S., Ciais, P., Krinner, G., Wang, T., Gouttevin, I., Mcguire, A. D., . . . Sueyoshi, T. (2016). Simulated high-latitude soil thermal dynamics during the past 4 decades. The Cryosphere, 10(1), 179-192. doi:10.5194/tc-10-179-2016
http://hdl.handle.net/2286/R.I.44929
op_rights http://rightsstatements.org/vocab/InC/1.0/
http://creativecommons.org/licenses/by/4.0
op_rightsnorm CC-BY
op_doi https://doi.org/10.5194/tc-10-179-2016
container_title The Cryosphere
container_volume 10
container_issue 1
container_start_page 179
op_container_end_page 192
_version_ 1766336389538906112
spelling ftarizonastateun:item:44929 2023-05-15T13:03:25+02:00 Simulated high-latitude soil thermal dynamics during the past 4 decades Peng, S. (Author) Ciais, P. (Author) Krinner, G. (Author) Wang, T. (Author) Gouttevin, I. (Author) McGuire, A. D. (Author) Lawrence, D. (Author) Burke, E. (Author) Chen, X. (Author) Decharme, B. (Author) Koven, C. (Author) MacDougall, A. (Author) Rinke, A. (Author) Saito, K. (Author) Zhang, W. (Author) Alkama, R. (Author) Bohn, Theodore (ASU author) Delire, C. (Author) Hajima, T. (Author) Ji, D. (Author) Lettenmaier, D. P. (Author) Miller, P. A. (Author) Moore, J. C. (Author) Smith, B. (Author) Sueyoshi, T. (Author) College of Liberal Arts and Sciences School of Earth and Space Exploration Julie Ann Wrigley Global Institute of Sustainability 2016-01-20 14 pages https://doi.org/10.5194/tc-10-179-2016 http://hdl.handle.net/2286/R.I.44929 eng eng CRYOSPHERE doi:10.5194/tc-10-179-2016 ISSN: 1994-0416 ISSN: 1994-0424 Peng, S., Ciais, P., Krinner, G., Wang, T., Gouttevin, I., Mcguire, A. D., . . . Sueyoshi, T. (2016). Simulated high-latitude soil thermal dynamics during the past 4 decades. The Cryosphere, 10(1), 179-192. doi:10.5194/tc-10-179-2016 http://hdl.handle.net/2286/R.I.44929 http://rightsstatements.org/vocab/InC/1.0/ http://creativecommons.org/licenses/by/4.0 CC-BY Text 2016 ftarizonastateun https://doi.org/10.5194/tc-10-179-2016 2018-06-30T22:52:38Z abstract: Soil temperature (T[subscript s]) change is a key indicator of the dynamics of permafrost. On seasonal and interannual timescales, the variability of T[subscript s] determines the active-layer depth, which regulates hydrological soil properties and biogeochemical processes. On the multi-decadal scale, increasing T[subscript s] not only drives permafrost thaw/retreat but can also trigger and accelerate the decomposition of soil organic carbon. The magnitude of permafrost carbon feedbacks is thus closely linked to the rate of change of soil thermal regimes. In this study, we used nine process-based ecosystem models with permafrost processes, all forced by different observation-based climate forcing during the period 1960–2000, to characterize the warming rate of T[subscript s] in permafrost regions. There is a large spread of T[subscript s] trends at 20 cm depth across the models, with trend values ranging from 0.010 ± 0.003 to 0.031 ± 0.005 °C yr[superscript −1]. Most models show smaller increase in T[subscript s] with increasing depth. Air temperature (Tsub>a) and longwave downward radiation (LWDR) are the main drivers of T[subscript s] trends, but their relative contributions differ amongst the models. Different trends of LWDR used in the forcing of models can explain 61 % of their differences in T[subscript s] trends, while trends of T[subscript a] only explain 5 % of the differences in T[subscript s] trends. Uncertain climate forcing contributes a larger uncertainty in T[subscript s] trends (0.021 ± 0.008 °C yr[superscript −1], mean ± standard deviation) than the uncertainty of model structure (0.012 ± 0.001 °C yr[superscript −1]), diagnosed from the range of response between different models, normalized to the same forcing. In addition, the loss rate of near-surface permafrost area, defined as total area where the maximum seasonal active-layer thickness (ALT) is less than 3 m loss rate, is found to be significantly correlated with the magnitude of the trends of T[subscript s] at 1 m depth across the models (R = −0.85, P = 0.003), but not with the initial total near-surface permafrost area (R = −0.30, P = 0.438). The sensitivity of the total boreal near-surface permafrost area to T[subscript s] at 1 m is estimated to be of −2.80 ± 0.67 million km[superscript 2 ]°C[superscript −1]. Finally, by using two long-term LWDR data sets and relationships between trends of LWDR and T[subscript s] across models, we infer an observation-constrained total boreal near-surface permafrost area decrease comprising between 39 ± 14 × 10[superscript 3] and 75 ± 14 × 10[superscript 3 ]km[superscript 2 ]yr[superscript −1] from 1960 to 2000. This corresponds to 9–18 % degradation of the current permafrost area. This article and any associated published material is distributed under the Creative Commons Attribution 3.0 License. View the article as published at: https://www.the-cryosphere.net/10/179/2016/ Text Active layer thickness permafrost The Cryosphere Arizona State University: ASU Digital Repository The Cryosphere 10 1 179 192

Similar Items