Miscellaneous methods for determination of unfrozen water content in frozen soils

•Reviewed five categories of methods for measuring unfrozen water or ice content;•Estimated the unfrozen soil water content with three empirical models;•The methods and models are evaluated, and the future development indicated. Frozen soil is a complex four-phase porous medium consisting of soil so...

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Veröffentlicht in:	Journal of hydrology (Amsterdam) 2024-03, Vol.631, p.130802, Article 130802
Hauptverfasser:	Feng, Shuna, Chen, Junru, Jones, Scott B., Flerchinger, Gerald, Dyck, Miles, Filipovic, Vilim, Hu, You, Si, Bingcheng, Lv, Jialong, Wu, Qingbai, He, Hailong
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Sprache:	eng
Schlagworte:	air climate change Dielectric permittivity freeze-thaw cycles frozen soils ice Ice content liquids microbial activity permeability porous media Soil freezing characteristic soil structure soil water soil water content solutes temperature thermodynamics Unfrozen water content water content
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container_title	Journal of hydrology (Amsterdam)
container_volume	631
creator	Feng, Shuna Chen, Junru Jones, Scott B. Flerchinger, Gerald Dyck, Miles Filipovic, Vilim Hu, You Si, Bingcheng Lv, Jialong Wu, Qingbai He, Hailong
description	•Reviewed five categories of methods for measuring unfrozen water or ice content;•Estimated the unfrozen soil water content with three empirical models;•The methods and models are evaluated, and the future development indicated. Frozen soil is a complex four-phase porous medium consisting of soil solid/rock, air, unfrozen/liquid water and ice at the subzero temperatures. Freeze-thaw cycles change the magnitude of total soil water content as well as the unfrozen water/ice ratio in frozen soil that affects soil structure and strength, infiltrability/permeability, water availability for microbial activity and chemical reactions, solute concentration and distribution, and thermodynamics. Accurate quantification of unfrozen water content is therefore critical to understand frozen soil hydrological, biogeochemical, thermal and mechanical properties and processes under climate change. Currently a variety of techniques and methods have been applied to obtain unfrozen water content in frozen soils. However, only few studies have attempted to review and synthesize these works. The objective of this study was therefore to review and collate currently available methods determining unfrozen water content in frozen soils. The principles, applications, advantages and limitations of these methods were reviewed and categorized into five categories: a pressure-based method, radioactive-methods, electromagnetic-methods, thermal-methods, and a sound-based method. Models for indirectly estimating unfrozen water content based on empirical temperature relationships, the soil water/moisture retention characteristic, and the vG-Clapeyron model, were also summarized. There is no direct method to estimate ice content but it can be indirectly calculated based on water balance (i.e., difference between total and unfrozen soil water content). The review is closed with a brief review of future needs and perspectives for simultaneous measurement of unfrozen water and ice contents in the laboratory and in the field.
doi_str_mv	10.1016/j.jhydrol.2024.130802
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Frozen soil is a complex four-phase porous medium consisting of soil solid/rock, air, unfrozen/liquid water and ice at the subzero temperatures. Freeze-thaw cycles change the magnitude of total soil water content as well as the unfrozen water/ice ratio in frozen soil that affects soil structure and strength, infiltrability/permeability, water availability for microbial activity and chemical reactions, solute concentration and distribution, and thermodynamics. Accurate quantification of unfrozen water content is therefore critical to understand frozen soil hydrological, biogeochemical, thermal and mechanical properties and processes under climate change. Currently a variety of techniques and methods have been applied to obtain unfrozen water content in frozen soils. However, only few studies have attempted to review and synthesize these works. The objective of this study was therefore to review and collate currently available methods determining unfrozen water content in frozen soils. The principles, applications, advantages and limitations of these methods were reviewed and categorized into five categories: a pressure-based method, radioactive-methods, electromagnetic-methods, thermal-methods, and a sound-based method. Models for indirectly estimating unfrozen water content based on empirical temperature relationships, the soil water/moisture retention characteristic, and the vG-Clapeyron model, were also summarized. There is no direct method to estimate ice content but it can be indirectly calculated based on water balance (i.e., difference between total and unfrozen soil water content). 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Frozen soil is a complex four-phase porous medium consisting of soil solid/rock, air, unfrozen/liquid water and ice at the subzero temperatures. Freeze-thaw cycles change the magnitude of total soil water content as well as the unfrozen water/ice ratio in frozen soil that affects soil structure and strength, infiltrability/permeability, water availability for microbial activity and chemical reactions, solute concentration and distribution, and thermodynamics. Accurate quantification of unfrozen water content is therefore critical to understand frozen soil hydrological, biogeochemical, thermal and mechanical properties and processes under climate change. Currently a variety of techniques and methods have been applied to obtain unfrozen water content in frozen soils. However, only few studies have attempted to review and synthesize these works. The objective of this study was therefore to review and collate currently available methods determining unfrozen water content in frozen soils. 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The review is closed with a brief review of future needs and perspectives for simultaneous measurement of unfrozen water and ice contents in the laboratory and in the field.</description><subject>air</subject><subject>climate change</subject><subject>Dielectric permittivity</subject><subject>freeze-thaw cycles</subject><subject>frozen soils</subject><subject>ice</subject><subject>Ice content</subject><subject>liquids</subject><subject>microbial activity</subject><subject>permeability</subject><subject>porous media</subject><subject>Soil freezing characteristic</subject><subject>soil structure</subject><subject>soil water</subject><subject>soil water content</subject><subject>solutes</subject><subject>temperature</subject><subject>thermodynamics</subject><subject>Unfrozen water content</subject><subject>water content</subject><issn>0022-1694</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2024</creationdate><recordtype>article</recordtype><recordid>eNqFkEtLxDAUhbNQcBz9CUKWblrz6mslMviCERF0HdLklklpkzHJKOOvt0Nn4c67uXDvOQfOh9AVJTkltLzp836zN8EPOSNM5JSTmrATtCCEsYyWjThD5zH2ZBrOxQK9vdioYRiUA7-LeIS08SbizgdsIEEYrVPJeod9h3euC_4HHP5W0wdr7xK4hK3Dx3v0dogX6LRTQ4TL416ij4f799VTtn59fF7drTPNBUuZBt4aUZkGmpq3FYGiKYzRlFFSm6rVpjCiFKqoRcNYwUylOqWqChrBaqBtw5foes7dBv-5g5jk-LeK5LTgjExQ6CQtZqkOPsYAndwGO6qwl5TIAzbZyyM2ecAmZ2yT73b2wdTjy0KQUVtwGowNoJM03v6T8As32Hxc</recordid><startdate>202403</startdate><enddate>202403</enddate><creator>Feng, Shuna</creator><creator>Chen, Junru</creator><creator>Jones, Scott B.</creator><creator>Flerchinger, Gerald</creator><creator>Dyck, Miles</creator><creator>Filipovic, Vilim</creator><creator>Hu, You</creator><creator>Si, Bingcheng</creator><creator>Lv, Jialong</creator><creator>Wu, Qingbai</creator><creator>He, Hailong</creator><general>Elsevier B.V</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7S9</scope><scope>L.6</scope><orcidid>https://orcid.org/0000-0002-5156-5090</orcidid><orcidid>https://orcid.org/0000-0002-7497-5033</orcidid><orcidid>https://orcid.org/0000-0001-7869-3677</orcidid><orcidid>https://orcid.org/0000-0001-9244-8280</orcidid><orcidid>https://orcid.org/0000-0003-4986-673X</orcidid></search><sort><creationdate>202403</creationdate><title>Miscellaneous methods for determination of unfrozen water content in frozen soils</title><author>Feng, Shuna ; 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Frozen soil is a complex four-phase porous medium consisting of soil solid/rock, air, unfrozen/liquid water and ice at the subzero temperatures. Freeze-thaw cycles change the magnitude of total soil water content as well as the unfrozen water/ice ratio in frozen soil that affects soil structure and strength, infiltrability/permeability, water availability for microbial activity and chemical reactions, solute concentration and distribution, and thermodynamics. Accurate quantification of unfrozen water content is therefore critical to understand frozen soil hydrological, biogeochemical, thermal and mechanical properties and processes under climate change. Currently a variety of techniques and methods have been applied to obtain unfrozen water content in frozen soils. However, only few studies have attempted to review and synthesize these works. The objective of this study was therefore to review and collate currently available methods determining unfrozen water content in frozen soils. 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subjects	air climate change Dielectric permittivity freeze-thaw cycles frozen soils ice Ice content liquids microbial activity permeability porous media Soil freezing characteristic soil structure soil water soil water content solutes temperature thermodynamics Unfrozen water content water content
title	Miscellaneous methods for determination of unfrozen water content in frozen soils
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