Neutron scattering quantification of unfrozen pore water in frozen mud

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Standard

Neutron scattering quantification of unfrozen pore water in frozen mud. / Gates, Will P.; Bordallo, Heloisa N.; Bouazza, Abdelmalek; Carnero-Guzman, Genaro Gonzalo; Aldridge, Laurence P.; Klapproth, Alice; Iles, Gail N.; Booth, Norman; Mole, Richard A.; Seydel, Tilo; Yu, Dehong; de Souza, Nicolas R.

I: Microporous and Mesoporous Materials, Bind 324, 111267, 01.09.2021.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Gates, WP, Bordallo, HN, Bouazza, A, Carnero-Guzman, GG, Aldridge, LP, Klapproth, A, Iles, GN, Booth, N, Mole, RA, Seydel, T, Yu, D & de Souza, NR 2021, 'Neutron scattering quantification of unfrozen pore water in frozen mud', Microporous and Mesoporous Materials, bind 324, 111267. https://doi.org/10.1016/j.micromeso.2021.111267

APA

Gates, W. P., Bordallo, H. N., Bouazza, A., Carnero-Guzman, G. G., Aldridge, L. P., Klapproth, A., Iles, G. N., Booth, N., Mole, R. A., Seydel, T., Yu, D., & de Souza, N. R. (2021). Neutron scattering quantification of unfrozen pore water in frozen mud. Microporous and Mesoporous Materials, 324, [111267]. https://doi.org/10.1016/j.micromeso.2021.111267

Vancouver

Gates WP, Bordallo HN, Bouazza A, Carnero-Guzman GG, Aldridge LP, Klapproth A o.a. Neutron scattering quantification of unfrozen pore water in frozen mud. Microporous and Mesoporous Materials. 2021 sep. 1;324. 111267. https://doi.org/10.1016/j.micromeso.2021.111267

Author

Gates, Will P. ; Bordallo, Heloisa N. ; Bouazza, Abdelmalek ; Carnero-Guzman, Genaro Gonzalo ; Aldridge, Laurence P. ; Klapproth, Alice ; Iles, Gail N. ; Booth, Norman ; Mole, Richard A. ; Seydel, Tilo ; Yu, Dehong ; de Souza, Nicolas R. / Neutron scattering quantification of unfrozen pore water in frozen mud. I: Microporous and Mesoporous Materials. 2021 ; Bind 324.

Bibtex

@article{71a6a586e5eb4f19ae7502c0b016237b,
title = "Neutron scattering quantification of unfrozen pore water in frozen mud",
abstract = "The Earth's polar regions are experiencing a greater frequency of freeze-thaw events throughout the polar summer, contributing to atmospheric methane and destabilising clay-rich sediments. Clays in soils tightly bind pore water and thus substantially modify freeze-thaw events. While temperatures of phase transitions for confined pore water may be precisely assessed using calorimetric or thermal analyses to -30 or -40 degrees C, neutron scattering directly probes how pores in clay minerals control ice formation and melting to lower temperatures. We apply elastic neutron scattering to accurately quantify the unfrozen water content of clay gels and unambiguously identify different pore-water environments by their freezing temperatures. Using this approach, we conclude that cryosuction controls water mobility in frozen soils in the absence of soluble salts to much lower temperatures than observed by other techniques. Dyanmics determined from neutron scattering indicates that water in clay gel pores thaws at much lower temperatures than currently considered, and thus pose potential risks for contaminant migration at sub freezing temperatures. The general poor strength of wet clays can significantly impact infrastructure in cold regions undergoing an increased frequency of freeze-thaw events.",
keywords = "Cyrosuction, Gel pores, Capillary pores, Clays, Neutron scattering, SOIL, DYNAMICS, DESORPTION, GELS, NMR, ICE",
author = "Gates, {Will P.} and Bordallo, {Heloisa N.} and Abdelmalek Bouazza and Carnero-Guzman, {Genaro Gonzalo} and Aldridge, {Laurence P.} and Alice Klapproth and Iles, {Gail N.} and Norman Booth and Mole, {Richard A.} and Tilo Seydel and Dehong Yu and {de Souza}, {Nicolas R.}",
year = "2021",
month = sep,
day = "1",
doi = "10.1016/j.micromeso.2021.111267",
language = "English",
volume = "324",
journal = "Zeolites",
issn = "1387-1811",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Neutron scattering quantification of unfrozen pore water in frozen mud

AU - Gates, Will P.

AU - Bordallo, Heloisa N.

AU - Bouazza, Abdelmalek

AU - Carnero-Guzman, Genaro Gonzalo

AU - Aldridge, Laurence P.

AU - Klapproth, Alice

AU - Iles, Gail N.

AU - Booth, Norman

AU - Mole, Richard A.

AU - Seydel, Tilo

AU - Yu, Dehong

AU - de Souza, Nicolas R.

PY - 2021/9/1

Y1 - 2021/9/1

N2 - The Earth's polar regions are experiencing a greater frequency of freeze-thaw events throughout the polar summer, contributing to atmospheric methane and destabilising clay-rich sediments. Clays in soils tightly bind pore water and thus substantially modify freeze-thaw events. While temperatures of phase transitions for confined pore water may be precisely assessed using calorimetric or thermal analyses to -30 or -40 degrees C, neutron scattering directly probes how pores in clay minerals control ice formation and melting to lower temperatures. We apply elastic neutron scattering to accurately quantify the unfrozen water content of clay gels and unambiguously identify different pore-water environments by their freezing temperatures. Using this approach, we conclude that cryosuction controls water mobility in frozen soils in the absence of soluble salts to much lower temperatures than observed by other techniques. Dyanmics determined from neutron scattering indicates that water in clay gel pores thaws at much lower temperatures than currently considered, and thus pose potential risks for contaminant migration at sub freezing temperatures. The general poor strength of wet clays can significantly impact infrastructure in cold regions undergoing an increased frequency of freeze-thaw events.

AB - The Earth's polar regions are experiencing a greater frequency of freeze-thaw events throughout the polar summer, contributing to atmospheric methane and destabilising clay-rich sediments. Clays in soils tightly bind pore water and thus substantially modify freeze-thaw events. While temperatures of phase transitions for confined pore water may be precisely assessed using calorimetric or thermal analyses to -30 or -40 degrees C, neutron scattering directly probes how pores in clay minerals control ice formation and melting to lower temperatures. We apply elastic neutron scattering to accurately quantify the unfrozen water content of clay gels and unambiguously identify different pore-water environments by their freezing temperatures. Using this approach, we conclude that cryosuction controls water mobility in frozen soils in the absence of soluble salts to much lower temperatures than observed by other techniques. Dyanmics determined from neutron scattering indicates that water in clay gel pores thaws at much lower temperatures than currently considered, and thus pose potential risks for contaminant migration at sub freezing temperatures. The general poor strength of wet clays can significantly impact infrastructure in cold regions undergoing an increased frequency of freeze-thaw events.

KW - Cyrosuction

KW - Gel pores

KW - Capillary pores

KW - Clays

KW - Neutron scattering

KW - SOIL

KW - DYNAMICS

KW - DESORPTION

KW - GELS

KW - NMR

KW - ICE

U2 - 10.1016/j.micromeso.2021.111267

DO - 10.1016/j.micromeso.2021.111267

M3 - Journal article

VL - 324

JO - Zeolites

JF - Zeolites

SN - 1387-1811

M1 - 111267

ER -

ID: 277226240