Komarov I.A., 2020. Thermodynamic description of phase and chemical equilibrium of water in frozen and freezing soils. Рart 1. Engineering Geology World, Vol. XV, No. 1, pp. 52–68, https://doi.org/10.25296/1993-5056-2020-15-1-52-68.
1. Ananyan A.A., Golovanova G.F., Volkova E.V., 1977. Study of the kaolin-water system by the spin echo method. In collection of papers V.F. Kiseleva, V.I. Kvlividze (eds), Bound water in dispersed systems, Issue 4. Publishing house of the Moscow State University, Moscow, pp. 172–178. (in Russian)
2. Brovka G.P., 1991. Heat and mass transfer in natural dispersed systems during freezing. Nauka i tekhnika, Minsk. (in Russian)
3. Viktorov M.M., 1977. Methods for calculating physical and chemical quantities and applied calculations. Himiya, Moscow. (in Russian)
4. Votyakov I.N., 1975. Physical and mechanical properties of frozen and thawing soils of Yakutia. Nauka, Novosibirsk. (in Russian)
5. Vyalov S.S. (ed.), 1983. Thermodynamic aspects of frozen soil mechanics. Nauka, Moscow. (in Russian)
6. Globus A.M., 1983. Physics of non-isothermal subsurface moisture exchange. Gidrometeoizdat, Leningrad. (in Russian)
7. Gorelik Ya.B., Kolunin V.S., 2002. Physics and modeling of cryogenic processes in the lithosphere. Publishing house of the Siberian Branch, Russian Academy of Sciences, Novosibirsk. (in Russian)
8. Grechishchev S.E., Chistotinov L.V., Shur Yu.L., 1984. Basics of modeling cryogenic physico-geological processes. Nauka, Moscow. (in Russian)
9. Grechishchev S.E., 1983. On the basics of thermorheology of cryogenic rocks. In collection of papers, Problems of geocryology. Nauka, Moscow, pp. 90–100. (in Russian)
10. Danielyan Yu.S., Yanitsky P.A., 1983. The specifity of nonequilibrium moisture ledistribution when freezing and thawing dispersed soils. Journal of Engineering Physics and Thermophysics, Vol. 44, No. 1, pp. 91–98. (in Russian)
11. Ershov E.D. (ed.), 1996. Fundamentals of geocryology. Part 2. Lithogenetic cryolithology. Publishing house of the Moscow State University, Moscow. (in Russian)
12. Zharikov V.A., 2005. Fundamentals of physical geochemistry. Publishing house of the Moscow State University, Moscow. (in Russian)
13. Ivanov N.S., 1967. Heat and mass transfer in frozen rocks. Nauka, Moscow. (in Russian)
14. Istomin V.A., Chuvilin E.M., Bukhanov B.A., 2017. Fast estimation of unfrozen water content in frozen soils. Earth’s Cryosphere,
Vol. XXI, No. 6, pp. 134–139, https://doi.org/10.21782/KZ1560-7496-2017-6(134-139). (in Russian)
15. Istomin V.A., Yakushev V.S., 1992. Gas hydrates in natural conditions. Nedra, Moscow. (in Russian)
16. Carathéodory K., 1964. About the foundations of thermodynamics. Development of modern physics. Nauka, Moscow, pp. 3–22. (in Russian)
17. Kvlividze V.I., Krasnushkin A.V., Yazinina I.V., 1980. Study of the state of water in clay minerals by nuclear magnetic resonance. In collection of papers V.F. Kiseleva, V.I. Kvlividze (eds), Bound water in dispersed systems, Issue 5. Publishing house of the Moscow State University, Moscow, pp. 99–104. (in Russian)
18. Komarov I.A., 2003. Thermodynamics and heat and mass transfer in dispersed frozen rocks. Nauchniy mir, Moscow. (in Russian)
19. Komarov I.A., Melchakova L.V., 2000. Specificity of the temperature dependence of heat capacity in dispersed rocks with an expanding structural cell. In collection of papers, Geophysical studies of the permafrost, Issue 3. Publishing house of the Pushchino Scientific Center of the Russian Academy of Sciences, Pushchino, pp. 122–131. (in Russian)
20. Komarov S.A., Mironov V.L., 2000. Microwave sounding of soils. Publishing house of the Siberian Branch, Russian Academy of Sciences, Novosibirsk. (in Russian)
21. Korolev V.A., 1983. Influence of temperature on the adsorption of moisture in clay soils. In collection of papers, Engineering geology and soil science issues, Issue 5. Publishing house of the Moscow State University, Moscow, pp. 115–130. (in Russian)
22. Leontev E.I., 1978. Modeling in petrophysics. Nedra, Moscow. (in Russian)
23. Nersesova Z.A., 1954. Instructions for determining the amount of unfrozen water and ice in frozen soils. In the book: Materials on laboratory studies of frozen soils, Issue 2. Publishing house of the USSR Academy of Sciences, Moscow, pp. 55–77. (in Russian)
24. Osipov V.I., 1979. The nature of strength and deformation properties of clay rocks. Publishing house of the Moscow State University, Moscow. (in Russian)
25. Rudd O.D., Ortle D.Kh., 1975. Experimental studies of the influence of pressure on the mechanism of frost heaving and growth-melting of ice in soils and glaciers. Proceedings of the 2nd International Conference, Issue 8, Yakytsk, 1975, pp. 232–243. (in Russian)
26. Tankaev R.U., 1982. Experimental study of ice melting in a hydrophilic dispersed system. Extended abstract of Ph.D. Thesis, Lomonosov Moscow State University, Moscow. (in Russian)
27. Tarasevich Yu.I., Ovcharenko F.D., 1975. Adsorption on clay minerals. Naukova dumka, Kiev. (in Russian)
28. Timofeev A.M., Starostin E.G., 1996. Investigation of the heat of crystallization of bound water in clayey soils. Materials of the
1st Conference of geocryologists of Russia, Moscow, 1996, pp. 3–8. (in Russian)
29. Saveliev B.A., 1971. Physics, chemistry and structure of natural ice and frozen rocks. Publishing house of the Academy of Sciences of the USSR, Moscow. (in Russian)
30. Williams P.D., 1972. Heat and mass transfer in freezing soils. In the book: Experimental studies of heat transfer processes in frozen rocks. Nauka, Moscow, pp. 14–19. (in Russian)
31. Tsytovich N.A., 1945. Towards the theory of the equilibrium state of water in frozen soils. Bulletin of the USSR Academy of Sciences. Geographic and Geophysical Series, Vol. 9, No. 5, pp. 493–502. (in Russian)
32. Tsytovich N.A., 1973. Mechanics of frozen soils. Vysshaya shkola, Moscow. (in Russian)
33. Cheverev V.G., Vidyapin I.Yu., Kondakov M.V., Motenko R.G., 2005. Determination of the content of unfrozen water in soils by sorptiondesorption isotherms. Earth’s Cryosphere, Vol. IX, No. 3, pp. 29–33. (in Russian)
34. Edlefsen N.Ye., Andersen A.B., 1966. Thermodynamics of soil moisture. In collection of papers, Thermodynamics of soil moisture. Gidrometeoizdat, Leningrad, pp. 5–273. (in Russian)
35. Anderson D.M., Tace A.R., McKim H.L., 1973. The unfrozen water and apparent spesific heat capacity of frozen soils. Permafrost, Proceedings of the 2nd International Conference, Washington, D.C., USA, 1973, рр. 289–295.
36. Anderson D.M., Hoeckstra P., 1965. Crystalization of clay-adsorbed water. Science, Vol. 149, Issue 3681, pp. 318–319,
https://doi.org/10.1126/science.149.3681.318.
37. Ershov E.D., Komarov I.A., Chuvilin E.M., Osipov V.I., Buldovich S.N., Lebedenko Yu.P., Cheverev V.G., Brouchkov A.V., Kuchukov E.Z., Shevchenko L.V., Kondakov V.V., Yazinin O.M., 2015. Principles of geocryology. Vol. 1. Physico-chemical bases of geocryology. Publishing house of the Lanzhou University Press, Lanzhou, China.
38. Komarov I.A., 2001. Unified thermodynamical model of phase, adsorption and chemical balance of the porous liquid in frozen grounds (part 1, part 2). Thermal engineering and sciences for cold regions, Proceedings of the 7th International Symposium, Seoul, Korea, 2001, рр. 187–191, 193–197.
39. Low P.F., Anderson D.M., Hoekstra P., 1968. Some thermodynamic relationships for soil at and below the freezing point. Water Resources Research, Vol. 4, Nо. 2, pр. 379–394.
40. Miller R.D., 1972. Freezing and heaving of saturated and unsaturated soils. Highway Research Report, No. 393, pp. 1–11,
URL: http://onlinepubs.trb.org/Onlinepubs/hrr/1972/393/393-001.pdf (accessed: 15 January 2020).
41. Pruppacher H.R., 1967. Some relations between the structure of the ice–solution interface and free growth rate of ice crystals insupercooled aqucous solutions. Journal of Colloid and Interface Science, Vol. 25, Issue 2, pp. 285–294.
42. Williams P.J., 1966. Movement of air through water in partially saturated soils. Nature, Vol. 212, pр. 1463–1464,
https://doi.org/10.1038/2121463.