Detailed detection of active layer freeze–thaw dynamics using quasi-continuous electrical resistivity tomography (Deception Island, Antarctica)

Climate-induced warming of permafrost soils is a global phenomenon, with regional and site-specific variations which are not fully understood. In this context, a 2-D automated electrical resistivity tomography (A-ERT) system was installed for the first time in Antarctica at Deception Island, associa...

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Published in:The Cryosphere
Main Authors: Farzamian, Mohammad, Vieira, Gonçalo, Monteiro Santos, Fernando A., Yaghoobi Tabar, Borhan, Hauck, Christian, Paz, Maria Catarina, Bernardo, Ivo, Ramos, Miguel, Pablo, Miguel Angel
Format: Text
Language:English
Published: 2020
Subjects:
Deception Island
Crater Lake
Active layer monitoring
Antarc*
Antarctica
Ice
permafrost
Online Access:https://doi.org/10.5194/tc-14-1105-2020
https://tc.copernicus.org/articles/14/1105/2020/
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spelling ftcopernicus:oai:publications.copernicus.org:tc74836 2023-05-15T13:02:49+02:00 Detailed detection of active layer freeze–thaw dynamics using quasi-continuous electrical resistivity tomography (Deception Island, Antarctica) Farzamian, Mohammad Vieira, Gonçalo Monteiro Santos, Fernando A. Yaghoobi Tabar, Borhan Hauck, Christian Paz, Maria Catarina Bernardo, Ivo Ramos, Miguel Pablo, Miguel Angel 2020-03-25 application/pdf https://doi.org/10.5194/tc-14-1105-2020 https://tc.copernicus.org/articles/14/1105/2020/ eng eng doi:10.5194/tc-14-1105-2020 https://tc.copernicus.org/articles/14/1105/2020/ eISSN: 1994-0424 Text 2020 ftcopernicus https://doi.org/10.5194/tc-14-1105-2020 2020-07-20T16:22:20Z Climate-induced warming of permafrost soils is a global phenomenon, with regional and site-specific variations which are not fully understood. In this context, a 2-D automated electrical resistivity tomography (A-ERT) system was installed for the first time in Antarctica at Deception Island, associated to the existing Crater Lake site of the Circumpolar Active Layer Monitoring – South Program (CALM-S) – site. This setup aims to (i) monitor subsurface freezing and thawing processes on a daily and seasonal basis and map the spatial and temporal variability in thaw depth and to (ii) study the impact of short-lived extreme meteorological events on active layer dynamics. In addition, the feasibility of installing and running autonomous ERT monitoring stations in remote and extreme environments such as Antarctica was evaluated for the first time. Measurements were repeated at 4 h intervals during a full year, enabling the detection of seasonal trends and short-lived resistivity changes reflecting individual meteorological events. The latter is important for distinguishing between (1) long-term climatic trends and (2) the impact of anomalous seasons on the ground thermal regime. Our full-year dataset shows large and fast temporal resistivity changes during the seasonal active layer freezing and thawing and indicates that our system setup can resolve spatiotemporal thaw depth variability along the experimental transect at very high temporal resolution. The largest resistivity changes took place during the freezing season in April, when low temperatures induce an abrupt phase change in the active layer in the absence of snow cover. The seasonal thawing of the active layer is associated with a slower resistivity decrease during October due to the presence of snow cover and the corresponding zero-curtain effect. Detailed investigation of the daily resistivity variations reveals several periods with rapid and sharp resistivity changes of the near-surface layers due to the brief surficial refreezing of the active layer in summer or brief thawing of the active layer during winter as a consequence of short-lived meteorological extreme events. These results emphasize the significance of the continuous A-ERT monitoring setup which enables detecting fast changes in the active layer during short-lived extreme meteorological events. Based on this first complete year-round A-ERT monitoring dataset on Deception Island, we believe that this system shows high potential for autonomous applications in remote and harsh polar environments such as Antarctica. The monitoring system can be used with larger electrode spacing to investigate greater depths, providing adequate monitoring at sites and depths where boreholes are very costly and the ecosystem is very sensitive to invasive techniques. Further applications may be the estimation of ice and water contents through petrophysical models or the calibration and validation of heat transfer models between the active layer and permafrost. Text Active layer monitoring Antarc* Antarctica Deception Island Ice permafrost Copernicus Publications: E-Journals Deception Island ENVELOPE(-60.633,-60.633,-62.950,-62.950) Crater Lake ENVELOPE(-60.667,-60.667,-62.983,-62.983) The Cryosphere 14 3 1105 1120
institution Open Polar
collection Copernicus Publications: E-Journals
op_collection_id ftcopernicus
language English
description Climate-induced warming of permafrost soils is a global phenomenon, with regional and site-specific variations which are not fully understood. In this context, a 2-D automated electrical resistivity tomography (A-ERT) system was installed for the first time in Antarctica at Deception Island, associated to the existing Crater Lake site of the Circumpolar Active Layer Monitoring – South Program (CALM-S) – site. This setup aims to (i) monitor subsurface freezing and thawing processes on a daily and seasonal basis and map the spatial and temporal variability in thaw depth and to (ii) study the impact of short-lived extreme meteorological events on active layer dynamics. In addition, the feasibility of installing and running autonomous ERT monitoring stations in remote and extreme environments such as Antarctica was evaluated for the first time. Measurements were repeated at 4 h intervals during a full year, enabling the detection of seasonal trends and short-lived resistivity changes reflecting individual meteorological events. The latter is important for distinguishing between (1) long-term climatic trends and (2) the impact of anomalous seasons on the ground thermal regime. Our full-year dataset shows large and fast temporal resistivity changes during the seasonal active layer freezing and thawing and indicates that our system setup can resolve spatiotemporal thaw depth variability along the experimental transect at very high temporal resolution. The largest resistivity changes took place during the freezing season in April, when low temperatures induce an abrupt phase change in the active layer in the absence of snow cover. The seasonal thawing of the active layer is associated with a slower resistivity decrease during October due to the presence of snow cover and the corresponding zero-curtain effect. Detailed investigation of the daily resistivity variations reveals several periods with rapid and sharp resistivity changes of the near-surface layers due to the brief surficial refreezing of the active layer in summer or brief thawing of the active layer during winter as a consequence of short-lived meteorological extreme events. These results emphasize the significance of the continuous A-ERT monitoring setup which enables detecting fast changes in the active layer during short-lived extreme meteorological events. Based on this first complete year-round A-ERT monitoring dataset on Deception Island, we believe that this system shows high potential for autonomous applications in remote and harsh polar environments such as Antarctica. The monitoring system can be used with larger electrode spacing to investigate greater depths, providing adequate monitoring at sites and depths where boreholes are very costly and the ecosystem is very sensitive to invasive techniques. Further applications may be the estimation of ice and water contents through petrophysical models or the calibration and validation of heat transfer models between the active layer and permafrost.
format Text
author Farzamian, Mohammad
Vieira, Gonçalo
Monteiro Santos, Fernando A.
Yaghoobi Tabar, Borhan
Hauck, Christian
Paz, Maria Catarina
Bernardo, Ivo
Ramos, Miguel
Pablo, Miguel Angel
spellingShingle Farzamian, Mohammad
Vieira, Gonçalo
Monteiro Santos, Fernando A.
Yaghoobi Tabar, Borhan
Hauck, Christian
Paz, Maria Catarina
Bernardo, Ivo
Ramos, Miguel
Pablo, Miguel Angel
Detailed detection of active layer freeze–thaw dynamics using quasi-continuous electrical resistivity tomography (Deception Island, Antarctica)
author_facet Farzamian, Mohammad
Vieira, Gonçalo
Monteiro Santos, Fernando A.
Yaghoobi Tabar, Borhan
Hauck, Christian
Paz, Maria Catarina
Bernardo, Ivo
Ramos, Miguel
Pablo, Miguel Angel
author_sort Farzamian, Mohammad
title Detailed detection of active layer freeze–thaw dynamics using quasi-continuous electrical resistivity tomography (Deception Island, Antarctica)
title_short Detailed detection of active layer freeze–thaw dynamics using quasi-continuous electrical resistivity tomography (Deception Island, Antarctica)
title_full Detailed detection of active layer freeze–thaw dynamics using quasi-continuous electrical resistivity tomography (Deception Island, Antarctica)
title_fullStr Detailed detection of active layer freeze–thaw dynamics using quasi-continuous electrical resistivity tomography (Deception Island, Antarctica)
title_full_unstemmed Detailed detection of active layer freeze–thaw dynamics using quasi-continuous electrical resistivity tomography (Deception Island, Antarctica)
title_sort detailed detection of active layer freeze–thaw dynamics using quasi-continuous electrical resistivity tomography (deception island, antarctica)
publishDate 2020
url https://doi.org/10.5194/tc-14-1105-2020
https://tc.copernicus.org/articles/14/1105/2020/
long_lat ENVELOPE(-60.633,-60.633,-62.950,-62.950)
ENVELOPE(-60.667,-60.667,-62.983,-62.983)
geographic Deception Island
Crater Lake
geographic_facet Deception Island
Crater Lake
genre Active layer monitoring
Antarc*
Antarctica
Deception Island
Ice
permafrost
genre_facet Active layer monitoring
Antarc*
Antarctica
Deception Island
Ice
permafrost
op_source eISSN: 1994-0424
op_relation doi:10.5194/tc-14-1105-2020
https://tc.copernicus.org/articles/14/1105/2020/
op_doi https://doi.org/10.5194/tc-14-1105-2020
container_title The Cryosphere
container_volume 14
container_issue 3
container_start_page 1105
op_container_end_page 1120
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