Ice Contact-Bonding in Air and in the Presence of an Aqueous Sodium Chloride Solution
Publication: Journal of Cold Regions Engineering
Volume 30, Issue 4
Abstract
Snow compacting on roads may become hazardous for traffic. Chemicals such as sodium chloride are therefore often used to prevent crust formation. Melting has been believed to be the mechanism through which a chemical does this. A recent study, however, indicates that reduced contact-bonding between ice crystals may be important. This hypothesis was tested by designing an experimental set-up capable of measuring the contact-bond strength between ice and a substrate. In this paper, ice–ice contact bonding was measured in air and in a sodium chloride solution. The study showed a statistically significant decrease in the median bonding force, from 0.57 N in air to 0.33 N in solution. The weakened contact-bonding in presence of a solution might explain the soft and noncompacting snow often seen on roads, an insight which might allow a more-efficient use of chemicals during snowfall.
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Acknowledgments
This study was sponsored by the Norwegian Public Roads Administration as a part of the project SaltSMART. The authors would like to thank Professor Erland M. Schulson of the Thayer School of Engineering at the Dartmouth College for valuable discussions and advice.
References
Adams, E., Alger, R. G., Chekan, J., Williams, F., and Valverde, R. (1992). “Persistence of reduced snow to pavement shear strength for two aggregate materials treated with CMA and NaCl.” Chapter 19, Chemical deicers and the environment, F. M. D’Itri, ed., Lewis Publishers, Chelsea, MI, 481–493.
Blackford, J. R., Jeffree, C. E., Noake, D. F. J., and Marmo, B. A. (2007). “Microstructural evolution in sintered ice particles containing NaCl observed by low-temperature scanning electron microscope.” Proc. Inst. Mech. Eng., Part L: J. Mater. Des. Appl., 221(3), 151–156.
Butt, H.-J., and Raterai, R. (1999). “Measurements of the surface tension and surface stress of solids.” Chapter 1, Surface characterization methods: Principles, techniques and applications, A. J. Milling, ed., Marcel Dekker, New York, 1–36.
Colbeck, S. (1980). “Thermodynamics of snow metamorphism due to variations in curvature.” J. Glaciol., 26(94), 291–301.
Cuelho, E., and Harwood, J. (2012). “Laboratory and field evaluation of anti-icing strategies.” Transp. Res. Rec., 2272, 144–151.
Fan, X., Ten, P., Clarke, C. A. B., and Zhang, Z. (2003). “Direct measurement of the adhesive force between ice particles by micromanipulation.” Powder Technol., 131(2–3), 105–110.
Faraday, M. (1860). “Note on regelation.” Proc. R. Soc. A, 10, 440–450.
Fay, L., and Shi, X. (2012). “Environmental impacts of chemicals for snow and ice control: State of the knowledge.” Water Air Soil Pollut., 223(5), 2751–2770.
Gubler, H. (1982). “Strength of bonds between ice grains after short contact times.” J. Glaciol., 28(100), 457–473.
Haisma, J., and Spierings, G. (2002). “Contact bonding, including direct-bonding in a historical and recent context of materials science and technology, physics and chemistry.” Mater. Sci. Eng.: Rep., 37(1–2), 1–60.
Haynes, W., Bruno, T. J., and Lide, D. R., eds. (2013). CRC handbook of chemistry and physics, 94th Ed., Taylor and Francis Group, London.
Ketcham, W., and Hobbs, P., V. (1969). “An experimental determination of surface energies of ice.” Philos. Mag., 19(162), 1161–1173.
Kobayashi, T., Kosugi, K., and Sato, T. (2004). “Consolidation process of snow on roads by vehicles.” Snow engineering, P. Bartelt, E. Adams, M. Christen, R. Sack, and A. Sato, eds., Taylor and Francis Group, London, 29–32.
Li, Y., Fang, Y., Seeley, N., Jungwirth, S., Jackson, E., and Shi, X. (2013). “Corrosion by chloride deicers on highway maintenance equipment.” Transp. Res. Rec., 2361, 106–113.
MATLAB R2013b [Computer software]. Mathworks, Natick, MA.
Messler, R. W. (1998). Principles of welding: Processes, physics, chemistry, and metallurgy, Wiley, Weinheim, Germany.
Minsk, D. L. (1998). Snow and ice control manual for transportation facilities, McGraw-Hill, New York.
Petrovic, J. (2003). “Review mechanical properties of ice and snow.” J. Mater. Sci., 38(1), 1–6.
Ramakrishna, D. M., and Viraraghavan, T. (2005). “Environmental impact of chemical deicers: A review.” Water Air Soil Pollut., 166(1), 49–63.
Raraty, L., and Tabor, D. (1958). “The adhesion and strength properties of ice.” Proc. R. Soc. London Ser. A: Math. Phys. Sci., 245(1241), 184–201.
Szabo, D., and Schneebeli, M. (2007). “Subsecond sintering of ice.” Appl. Phys. Lett., 90(15), 151916 1–151916 3.
Tusima, K. (1985). “Grain coarsening of snow particles immersed in water and solutions.” Ann. Glaciol., 6, 126–129.
Wåhlin, J., Leisinger, S., and Klein-Paste, A. (2014). “The effect of sodium chloride solution on the hardness of compacted snow.” Cold Reg. Sci. Technol., 102, 1–7.
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© 2016 American Society of Civil Engineers.
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Received: Dec 11, 2014
Accepted: Nov 12, 2015
Published online: Feb 29, 2016
Discussion open until: Jul 29, 2016
Published in print: Dec 1, 2016
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