264 BIBLIOGRAPHY Stoimenova, E., Datcheva, M. & Sch<strong>an</strong>z, T. (2003b), Statistical modeling <strong>of</strong> the soil-water characteristic curve for geotechnical data, in ‘1st International Conference: Mathematics <strong>an</strong>d Informatics for Industry’, Thessaloniki, Greece, pp. 356–366. Stoimenova, E., Datcheva, M. & Sch<strong>an</strong>z, T. (2005), Statistical approach in soil-water charac- teristic curve modelling, in T. Sch<strong>an</strong>z, ed., ‘<strong>Unsaturated</strong> Soils: Numerical <strong>an</strong>d Theoretical Approaches, Vol. II’, Springer Proceedings in Physics 94, Springer-Verlag, Berlin Heidel- berg, pp. 189–200. Stoimenova, E., Lins, Y., Datcheva, M. & Sch<strong>an</strong>z, T. (2006), Inverse modelling <strong>of</strong> soil hydraulic characteristic functions, in K. Gürlebeck & C. Könke, eds, ‘17th In- ternational Conference on the Application <strong>of</strong> Computer Science <strong>an</strong>d Mathematics in Architecture <strong>an</strong>d Civil Engineering’, Weimar, Germ<strong>an</strong>y. http://euklid.bauing.uni- weimar.de/templates/papers/f105.pdf. Suw<strong>an</strong>sawat, S. (1997), Using time domain reflectometry for measuring water content in compacted clays, Master’s thesis, University <strong>of</strong> Wisconsin-Madison. Suw<strong>an</strong>sawat, S. & Benson, C. H. (1999), ‘Cell size for water content-dielectric const<strong>an</strong>t cali- bratios for time domain reflectometry’, Geotechnical Testing Journal 22, 3–12. Talsma, T. (1970), ‘Hysteresis in two s<strong>an</strong>ds <strong>an</strong>d <strong>an</strong> independent domain model’, Water Re- sources Research 6, 964–970. Tar<strong>an</strong>tino, A. & Mongiovi, L. (2002), ‘Calibration <strong>of</strong> tensiometer for direct measurement <strong>of</strong> matric suction’, Géotechnique 53(1), 137–141. Tar<strong>an</strong>tino, A., Romero, E. & Cui, Y. J. (2008), ‘Special issue on laboratory <strong>an</strong>d field testing <strong>of</strong> unsaturated soils’, Geotechnical <strong>an</strong>d Geological Engineering 26(6). Terzaghi, K. (1943), Theoretical soil mech<strong>an</strong>ics, Wiley, New York. Toorm<strong>an</strong>, A. F. & Wierenga, P. J. (1992), ‘Parameter estimation <strong>of</strong> hydraulic properties from one-step outflow data’, Water Resources Research 28(11), 3021–3028. Topp, G. C. (1969), ‘Soil water hysteresis measured in a s<strong>an</strong>dy loam compared with the hysteresis domain model’, Soil Science Society <strong>of</strong> America Journal (33), 645–651. Topp, G. C. (1971a), ‘Soil water hysteresis on silt loam <strong>an</strong>d clay loam soils’, Water Resources Research 7(4), 914–920. Topp, G. C. (1971b), ‘Soil-water hysteresis: The domain model theory extended to pore interaction conditions’, Soil Science Society <strong>of</strong> America Journal 35, 219–225.
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Hydro-Mechanical Properties of Part
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Acknowledgement The present dissert
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