Findings of field and experimental studies of pedotransfer capability of nickel and platinum nanoparticles in the profile of Albeluvisols Haplic of the sub-boreal forest in the south-east of the Western Siberia were presented. Results of the surveys testify to the effect that major factors affecting the migration capability include large biogenic interstices and main cracks that act as transport channels for nanoparticles, as well as thermodynamic (φ-) potentials of particles that define the intensity of surface electrostatic interactions with walls of soil interstices.
Duester, L., Prasse, C., Vogel, J.V., Vink, J.P.M., Schaumann, G.E., 2011. Translocation of Sb and Ti in an undisturbed floodplain soil after application of Sb2O3 and TiO2 nanoparticles to the surface. Journal of Environmental Monitoring, 13, 1204-1211.
Fanga, J., Shana, X.Q., Wena, B., Lina, J.M., Owens, G., 2009. Stability of titania nanoparticles in soil suspensions and transport in saturated homogeneous soil columns. Environmental Pollution 157(4), 1101-1109.
Jaisi, D.P., Elimelech M., 2009. Single-Walled Carbon Nanotubes Exhibit Limited Transport in Soil Columns Environ. Environmental Science Technology 43(24), 9161–9166.
Li, W., Xu, J., Huang, P.M., 2010. Extraction of Nanoparticles from Argosols and Ferrosols. Molecular Environmental Soil Science at the Interfaces in the Earth’s Critical Zone 4, 275-278.
Vadyunina, A.F., Korchagin, Z.A., 1986. Methods of study of the physical properties of soils, Moscow: Agropromizdat, 416.
Loyko, S.V., Gerasko, L.I., Kulizhsky, S.P., 2011. Grouping the carriers of soil memory (the case of the northern area of chernovaya taiga). Bulletin of the Tomsk State University. Biology 3(15), 38-49.
Syso, A.I., 2007. Patterns of distribution of chemical elements in the soil-forming rocks and soils of Western Siberia. Novosibirsk: Publishing House of the Russian Academy of Sciences, 227.
Kovenya, S.V., Mel, M., Freed, A., 1972. Research on the role of mechanical forces and geometric conditions in the movement of fine particles in the soil columns. Soil Science 10, 133-140.
Year 2013,
Volume: 2 Issue: 2, 90 - 96, 01.06.2013
Duester, L., Prasse, C., Vogel, J.V., Vink, J.P.M., Schaumann, G.E., 2011. Translocation of Sb and Ti in an undisturbed floodplain soil after application of Sb2O3 and TiO2 nanoparticles to the surface. Journal of Environmental Monitoring, 13, 1204-1211.
Fanga, J., Shana, X.Q., Wena, B., Lina, J.M., Owens, G., 2009. Stability of titania nanoparticles in soil suspensions and transport in saturated homogeneous soil columns. Environmental Pollution 157(4), 1101-1109.
Jaisi, D.P., Elimelech M., 2009. Single-Walled Carbon Nanotubes Exhibit Limited Transport in Soil Columns Environ. Environmental Science Technology 43(24), 9161–9166.
Li, W., Xu, J., Huang, P.M., 2010. Extraction of Nanoparticles from Argosols and Ferrosols. Molecular Environmental Soil Science at the Interfaces in the Earth’s Critical Zone 4, 275-278.
Vadyunina, A.F., Korchagin, Z.A., 1986. Methods of study of the physical properties of soils, Moscow: Agropromizdat, 416.
Loyko, S.V., Gerasko, L.I., Kulizhsky, S.P., 2011. Grouping the carriers of soil memory (the case of the northern area of chernovaya taiga). Bulletin of the Tomsk State University. Biology 3(15), 38-49.
Syso, A.I., 2007. Patterns of distribution of chemical elements in the soil-forming rocks and soils of Western Siberia. Novosibirsk: Publishing House of the Russian Academy of Sciences, 227.
Kovenya, S.V., Mel, M., Freed, A., 1972. Research on the role of mechanical forces and geometric conditions in the movement of fine particles in the soil columns. Soil Science 10, 133-140.
Kulizhsky, S., Loyko, S., & Lim, A. (2013). Pedotransfer capacity of nickel and platinum nanoparticles in Albeluvisols Haplic in the South-East of the Western Siberia. Eurasian Journal of Soil Science, 2(2), 90-96.