Cryosuction

Cryosuction is the concept of negative pressure in freezing liquids so that more liquid is sucked into the freezing zone. In soil, the transformation of liquid water to ice in the soil pores causes water to migrate through soil pores to the freezing zone through capillary action.^[1] ^[2] Fine-grained soils such as clays and silts enables greater negative pressures than more coarse-grained soils due to the smaller pore size. In periglacial environments, this mechanism is highly significant and it is the predominant process in ice lens formation in permafrost areas.^[3]

As of 2001, several models for ice-lens formation by cryosuction existed, among others the hydrodynamic model and the Pre-melting model, many of them based on the Clausius–Clapeyron relation with various assumptions, yielding cryosuction potentials of 11 to 12 atm per degree Celsius below zero depending on pore size.^[4]

In 2023, experiments from the ETH Zurich were published, in which the process could be observed in a confocal microscope. In single-crystal experiments the rate of ice growth was slow, but with polycrystalline ice there were many more channels to suck in water to grow ice. How solutes in the water influence cryosuction is still unexplored.^[5]

References

^ Williams, P.J.; M.W. Smith (1991). "The Frozen Earth: Fundamentals of Geocryology". Polar Record. 27 (163): 370. doi:10.1017/S0032247400013231.
^ Hohmann, Maria (March 1997). "Soil freezing -- the concept of soil water potential. State of the art". Cold Regions Science and Technology. 25 (2): 101–110. Bibcode:1997CRST...25..101H. doi:10.1016/S0165-232X(96)00019-5. ISSN 0165-232X.
^ Doré, Guy (2004). "Development and Validation of the Thaw-weakening Index". International Journal of Pavement Engineering. 5 (4): 185–192. doi:10.1080/10298430412331317464. ISSN 1029-8436. S2CID 136685950.
^ Davis, Neil (2001). Permafrost: A Guide to Frozen Ground in Transition. University of Alaska Press. p. 351. ISBN 978-1-889963-19-8.
^ Katherine Wright Liquid Veins Give Ice Its Road-Wrecking Power November 16, 2023, Physics Magazine 16, 194

External links

Cryosuction Cryosphere glossary, National Snow and Ice Data Center, Canada, accessed 22 November 2023

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[1] Williams, P.J.; M.W. Smith (1991). "The Frozen Earth: Fundamentals of Geocryology". Polar Record. 27 (163): 370. doi:10.1017/S0032247400013231.

[2] Hohmann, Maria (March 1997). "Soil freezing -- the concept of soil water potential. State of the art". Cold Regions Science and Technology. 25 (2): 101–110. Bibcode:1997CRST...25..101H. doi:10.1016/S0165-232X(96)00019-5. ISSN 0165-232X.

[3] Doré, Guy (2004). "Development and Validation of the Thaw-weakening Index". International Journal of Pavement Engineering. 5 (4): 185–192. doi:10.1080/10298430412331317464. ISSN 1029-8436. S2CID 136685950.

[4] Davis, Neil (2001). Permafrost: A Guide to Frozen Ground in Transition. University of Alaska Press. p. 351. ISBN 978-1-889963-19-8.

[5] Katherine Wright Liquid Veins Give Ice Its Road-Wrecking Power November 16, 2023, Physics Magazine 16, 194

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References

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