Hydraulic Conductivity Measurement for Three Frozen and Unfrozen Soils in the Red River of the North Basin

Roy, Debjit; Jia, Xinhua; Chu, Xuefeng; Jacobs, Jennifer M.

doi:10.13031/trans.14224

Cited by 3 publications

(2 citation statements)

References 32 publications

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“…Considering all the peat samples, the average K s values of peat decreased as the average K s values are much higher than the threshold values (0.8 × 10 −5 m s −1 for site 1 and 0.2 × 10 −5 m s −1 for site 2). It has been reported that the response of hydraulic conductivity to freeze-thaw cycles is related to the initial soil moisture content (Roy et al, 2021). The soil organic matter (76.5 ± 0.4%) and the soil moisture content (0.67 ± 0.01 cm 3 cm −3 ) before freezing of site 2 samples were significantly higher than for site 1 samples (p < 0.01), which may be the reasons for the different threshold values.…”

Section: Figurementioning

confidence: 99%

Freeze-thaw cycles alter soil hydro-physical properties and dissolved organic carbon release from peat

Liu

Rezanezhad²,

Žák³

et al. 2022

Front. Environ. Sci.

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The ongoing climate warming is likely to increase the frequency of freeze-thaw cycles (FTCs) in cold-temperate peatland regions. Despite the importance of soil hydro-physical properties in water and carbon cycling in peatlands, the impacts of FTCs on peat properties as well as carbon sequestration and release remain poorly understood. In this study, we collected undisturbed topsoil samples from two drained lowland fen peatlands to investigate the impact of FTCs on hydro-physical properties as well as dissolved organic carbon (DOC) fluxes from peat. The soil samples were subject to five freeze-thaw treatments, including a zero, one, three, five, ten cycles (FTC0, FTC1, FTC3, FTC5, and FTC10, respectively). Each FTC was composed of 24 h of freezing (−5°C) and 24 h of thawing (5°C) and the soil moisture content during the freeze-thaw experiment was adjusted to field capacity. The results showed that the FTCs substantially altered the saturated hydraulic conductivity (Ks) of peat. For peat samples with low initial Ks values (e.g., < 0.2 × 10−5 m s−1), Ks increased after FTCs. In contrast, the Ks of peat decreased after freeze-thaw, if the initial Ks was comparably high (e.g., > 0.8 × 10−5 m s−1). Overall, the average Ks values of peatlands decreased after FTCs. The reduction in Ks values can be explained by the changes in macroporosity. The DOC experiment results revealed that the FTCs could increase DOC concentrations in leachate, but the DOC fluxes decreased mainly because of a reduction in water flow rate as well as Ks. In conclusion, soil hydraulic properties of peat (e.g., Ks) are affected by freezing and thawing. The dynamics of soil hydraulic properties need to be explicitly addressed in the quantification and modelling of the water flux and DOC release from peatlands.

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Section: Figurementioning

confidence: 99%

Freeze-thaw cycles alter soil hydro-physical properties and dissolved organic carbon release from peat

Liu

Rezanezhad²,

Žák³

et al. 2022

Front. Environ. Sci.

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“…(1) the need for controlling frost heave (Hayashi, 2013;Nixon, 1991); (2) the need for establishing and improving the prediction model (Harlan, 1973;Li et al, 2018;Ming et al, 2016); (3) the need for predicting spring flood caused by snowmelt in seasonally frozen region (Roy et al, 2020(Roy et al, , 2021. Recently, with the application of an artificial freezing method for containment of hazardous solid/liquid waste contaminants (Wagner, 2013), the study on the hydraulic conductivity of frozen soil has flourished once again.…”

Section: Introductionmentioning

confidence: 99%

A hydraulic conductivity model of frozen soils with the consideration of water films

Feng

Pei

Zhang

et al. 2022

European J Soil Science

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Accurate evaluation of water migration in frozen soils requires the determination of hydraulic conductivity. Most classical predictive models of hydraulic conductivity rely on the pore bundle concept that only accounts for capillary flow and neglects the water film flow. This may underestimate the hydraulic conductivity of frozen soil. In this study, water in the capillary tube was divided into free water and water films with different dynamic viscosities. Then, a novel prediction model for hydraulic conductivity of frozen soil was proposed based on the capillary flow theory. The model parameters can be easily obtained from laboratory tests. The predicted results showed good agreement with tested hydraulic conductivity of 12 frozen soils. When the temperature decreases from 0 to À1 C, the contribution

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Seasonal soil freeze/thaw variability across North America via ensemble land surface modeling

Moradi

Cho

Jacobs

et al. 2023

Cold Regions Science and Technology

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Hydraulic Conductivity Measurement for Three Frozen and Unfrozen Soils in the Red River of the North Basin

Cited by 3 publications

References 32 publications

Freeze-thaw cycles alter soil hydro-physical properties and dissolved organic carbon release from peat

Freeze-thaw cycles alter soil hydro-physical properties and dissolved organic carbon release from peat

A hydraulic conductivity model of frozen soils with the consideration of water films

Seasonal soil freeze/thaw variability across North America via ensemble land surface modeling

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