Electrical and seismic response of saline permafrost soil during freeze - Thaw transition

© 2017 We conducted laboratory studies on the geophysical signals from Arctic saline permafrost soils to help understand the physical and mechanical processes during freeze-thaw cycles. Our results revealed low electrical resistivity (< 20 Ωm) and elastic moduli (7.7 GPa for Young's modulus...

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Published in:Journal of Applied Geophysics
Main Authors: Wu, Y, Nakagawa, S, Kneafsey, TJ, Dafflon, B, Hubbard, S
Format: Article in Journal/Newspaper
Language:English
Published: eScholarship, University of California 2017
Subjects:
Arctic
Ice
permafrost
Online Access:http://www.escholarship.org/uc/item/5tk221nr
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spelling ftcdlib:qt5tk221nr 2023-05-15T15:14:56+02:00 Electrical and seismic response of saline permafrost soil during freeze - Thaw transition Wu, Y Nakagawa, S Kneafsey, TJ Dafflon, B Hubbard, S 16 - 26 2017-11-01 application/pdf http://www.escholarship.org/uc/item/5tk221nr english eng eScholarship, University of California qt5tk221nr http://www.escholarship.org/uc/item/5tk221nr public Wu, Y; Nakagawa, S; Kneafsey, TJ; Dafflon, B; & Hubbard, S. (2017). Electrical and seismic response of saline permafrost soil during freeze - Thaw transition. Journal of Applied Geophysics, 146, 16 - 26. doi:10.1016/j.jappgeo.2017.08.008. Lawrence Berkeley National Laboratory: Retrieved from: http://www.escholarship.org/uc/item/5tk221nr article 2017 ftcdlib https://doi.org/10.1016/j.jappgeo.2017.08.008 2018-09-28T22:52:49Z © 2017 We conducted laboratory studies on the geophysical signals from Arctic saline permafrost soils to help understand the physical and mechanical processes during freeze-thaw cycles. Our results revealed low electrical resistivity (< 20 Ωm) and elastic moduli (7.7 GPa for Young's modulus and 2.9 GPa for shear modulus) at temperatures down to ~− 10 °C, indicating the presence of a significant amount of unfrozen saline water under the current field conditions. The spectral induced polarization signal showed a systematic shift during the freezing process, affected by concurrent changes of temperature, salinity, and ice formation. An anomalous induced polarization response was first observed during the transient period of supercooling and the onset of ice nucleation. Seismic measurements showed a characteristic maximal attenuation at the temperatures immediately below the freezing point, followed by a decrease with decreasing temperature. The calculated elastic moduli showed a non-hysteric response during the freeze – thaw cycle, which was different from the concurrently measured electrical resistivity response where a differential resistivity signal is observed depending on whether the soil is experiencing freezing or thawing. The differential electrical resistivity signal presents challenges for unfrozen water content estimation based on Archie's law. Using an improved formulation of Archie's law with a variable cementation exponent, the unfrozen water content estimation showed a large variation depending on the choice of the resistivity data during either a freezing or thawing cycle. Combining the electrical and seismic results, we suggest that, rather than a large hysteresis in the actual unfrozen water content, the shift of the resistivity response may reflect the changes of the distribution pattern of the unfrozen water (or ice) in the soil matrix during repeated freeze and thaw processes. Collectively, our results provide an improved petrophysical understanding of the physical and mechanical properties of saline permafrost during freeze – thaw transitions, and suggest that large uncertainty may exist when estimating the unfrozen water content using electrical resistivity data. Article in Journal/Newspaper Arctic Ice permafrost University of California: eScholarship Arctic Journal of Applied Geophysics 146 16 26
institution Open Polar
collection University of California: eScholarship
op_collection_id ftcdlib
language English
description © 2017 We conducted laboratory studies on the geophysical signals from Arctic saline permafrost soils to help understand the physical and mechanical processes during freeze-thaw cycles. Our results revealed low electrical resistivity (< 20 Ωm) and elastic moduli (7.7 GPa for Young's modulus and 2.9 GPa for shear modulus) at temperatures down to ~− 10 °C, indicating the presence of a significant amount of unfrozen saline water under the current field conditions. The spectral induced polarization signal showed a systematic shift during the freezing process, affected by concurrent changes of temperature, salinity, and ice formation. An anomalous induced polarization response was first observed during the transient period of supercooling and the onset of ice nucleation. Seismic measurements showed a characteristic maximal attenuation at the temperatures immediately below the freezing point, followed by a decrease with decreasing temperature. The calculated elastic moduli showed a non-hysteric response during the freeze – thaw cycle, which was different from the concurrently measured electrical resistivity response where a differential resistivity signal is observed depending on whether the soil is experiencing freezing or thawing. The differential electrical resistivity signal presents challenges for unfrozen water content estimation based on Archie's law. Using an improved formulation of Archie's law with a variable cementation exponent, the unfrozen water content estimation showed a large variation depending on the choice of the resistivity data during either a freezing or thawing cycle. Combining the electrical and seismic results, we suggest that, rather than a large hysteresis in the actual unfrozen water content, the shift of the resistivity response may reflect the changes of the distribution pattern of the unfrozen water (or ice) in the soil matrix during repeated freeze and thaw processes. Collectively, our results provide an improved petrophysical understanding of the physical and mechanical properties of saline permafrost during freeze – thaw transitions, and suggest that large uncertainty may exist when estimating the unfrozen water content using electrical resistivity data.
format Article in Journal/Newspaper
author Wu, Y
Nakagawa, S
Kneafsey, TJ
Dafflon, B
Hubbard, S
spellingShingle Wu, Y
Nakagawa, S
Kneafsey, TJ
Dafflon, B
Hubbard, S
Electrical and seismic response of saline permafrost soil during freeze - Thaw transition
author_facet Wu, Y
Nakagawa, S
Kneafsey, TJ
Dafflon, B
Hubbard, S
author_sort Wu, Y
title Electrical and seismic response of saline permafrost soil during freeze - Thaw transition
title_short Electrical and seismic response of saline permafrost soil during freeze - Thaw transition
title_full Electrical and seismic response of saline permafrost soil during freeze - Thaw transition
title_fullStr Electrical and seismic response of saline permafrost soil during freeze - Thaw transition
title_full_unstemmed Electrical and seismic response of saline permafrost soil during freeze - Thaw transition
title_sort electrical and seismic response of saline permafrost soil during freeze - thaw transition
publisher eScholarship, University of California
publishDate 2017
url http://www.escholarship.org/uc/item/5tk221nr
op_coverage 16 - 26
geographic Arctic
geographic_facet Arctic
genre Arctic
Ice
permafrost
genre_facet Arctic
Ice
permafrost
op_source Wu, Y; Nakagawa, S; Kneafsey, TJ; Dafflon, B; & Hubbard, S. (2017). Electrical and seismic response of saline permafrost soil during freeze - Thaw transition. Journal of Applied Geophysics, 146, 16 - 26. doi:10.1016/j.jappgeo.2017.08.008. Lawrence Berkeley National Laboratory: Retrieved from: http://www.escholarship.org/uc/item/5tk221nr
op_relation qt5tk221nr
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op_rights public
op_doi https://doi.org/10.1016/j.jappgeo.2017.08.008
container_title Journal of Applied Geophysics
container_volume 146
container_start_page 16
op_container_end_page 26
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