254 BIBLIOGRAPHY J<strong>an</strong>bu, N. (1969), The resist<strong>an</strong>ce concept applied to deformation <strong>of</strong> soils, in ‘7th Interna- tional Soil Mech<strong>an</strong>ics <strong>an</strong>d Foundation Engineering Conference’, A. A. Balkema, Rotterdam, Boston, Mexico City, pp. 191–196. J<strong>an</strong>g, D. J. (1997), Qu<strong>an</strong>tification <strong>of</strong> s<strong>an</strong>d structure <strong>an</strong>d its evolution during shearing using image <strong>an</strong>alysis, PhD thesis, Georgia Institute <strong>of</strong> Technology, Atl<strong>an</strong>ta. J<strong>an</strong>g, D. J., Frost, J. D. & Park, J. Y. (1999), ‘Preparation <strong>of</strong> epoxy imgregnated s<strong>an</strong>d coupons for image <strong>an</strong>alysis’, Geotechnical Testing Journal 22(2), 147–158. Jaynes, D. B. (1984), ‘Comparison <strong>of</strong> soil-water hysteresis models’, Journal <strong>of</strong> <strong>Hydro</strong>logy 75, 287–299. Jennings, J. E. (1961), A revised effective stress law for use in the prediction <strong>of</strong> the behavior <strong>of</strong> unsaturated soils, in ‘Pore Pressure <strong>an</strong>d Suction in Soils’, London, Butterworth, pp. 26–30. Jennings, J. E. & Burl<strong>an</strong>d, J. B. (1962), ‘Limitations to the use <strong>of</strong> effective stresses in partly saturated soils’, Géotechnique 2(12), 125–144. Johnston, L. N. (1942), ‘Water permeable jacketed thermal radiators as indicators <strong>of</strong> field capacity <strong>an</strong>d perm<strong>an</strong>ent wilting percentage in soils’, Soil Science 54, 123–126. Kassiff, G. & Shalom, A. B. (1971), ‘Experimental relationship between swell pressure <strong>an</strong>d suction’, Géotechnique 21, 245–255. Kelleners, T. J., Soppe, R. W. O., Robinson, D. A., Schaap, M. G., Ayars, J. & Skaggs, T. H. (2004), ‘Calibration <strong>of</strong> capacit<strong>an</strong>ce probe sensors using electric circuit theory’, Soil Science Society <strong>of</strong> America Journal 68, 430–439. Klute, A. (1965), Laboratory measurement <strong>of</strong> hydraulic conductivity <strong>of</strong> unsaturated soils, in C. A. Black, ed., ‘Methods <strong>of</strong> soil <strong>an</strong><strong>an</strong>lysis’, Americ<strong>an</strong> Society <strong>of</strong> Agronomy (ASA), Madison, WI, U.S.A., pp. 253–261. Klute, A. (1972), ‘The determination <strong>of</strong> the hydraulic condcutivity <strong>an</strong>d diffusivity <strong>of</strong> unsatu- rated soils’, Soil Science 113(4), 264–276. Klute, A. (1986), Water retention: laboratory methods, in A. Klute, ed., ‘Methods <strong>of</strong> Soil <strong>an</strong>al- ysis. Part 1. Physical <strong>an</strong>d mineralogical methods’, Americ<strong>an</strong> Society <strong>of</strong> Agronomy (ASA) <strong>an</strong>d Soil Science Society <strong>of</strong> America (SSSA), Madison, WI, U.S.A., pp. 635–662. Klute, A. & Dirksen, C. (1986a), Hydraulic conductivity <strong>an</strong>d diffusivity: laboratory methods, in A. Klute, ed., ‘Methods <strong>of</strong> Soil <strong>an</strong>alysis. Part 1. Physical <strong>an</strong>d mineralogical methods’, Americ<strong>an</strong> Society <strong>of</strong> Agronomy (ASA) <strong>an</strong>d Soil Science Society <strong>of</strong> America (SSSA), Madi- son, WI, U.S.A., pp. 687–734.
BIBLIOGRAPHY 255 Klute, A. & Dirksen, C. (1986b), Hydraulic conductivity <strong>an</strong>d diffusivity: Laboratory methods, in A. Klute, ed., ‘Methods <strong>of</strong> Soil <strong>an</strong>alysis. Part 1. Physical <strong>an</strong>d mineralogical methods’, Americ<strong>an</strong> Society <strong>of</strong> Agronomy (ASA) <strong>an</strong>d Soil Science Society <strong>of</strong> America (SSSA), Madi- son, WI, U.S.A., pp. 687–734. Klute, A., Whisler, F. D. & Scott, E. J. (1964), ‘Soil water diffusivity <strong>an</strong>d hysteresis data from radial flow pressure cells’, Soil Science Society <strong>of</strong> America Journal 28, 160–164. Kool, J. B., Parker, J. C. & v<strong>an</strong> Genuchten, M. T. (1985a), ‘Determining soil hydraulic properties from one-step outflow experiments by parameter estimation: I. Theory <strong>an</strong>d numerical studies’, Soil Science Society <strong>of</strong> America Journal 49, 1348–1354. Kool, J. B., Parker, J. C. & v<strong>an</strong> Genuchten, M. T. (1985b), ‘Determining soil hydraulic properties from one-step outflow experiments by parameter estimation: II. Experimental studies’, Soil Science Society <strong>of</strong> America Journal 49, 1354–1359. Kovacs, G. (1981), Seepage hydraulics, Elsevier Science Publisher, Amsterdam. Krahn, J. & Fredlund, D. G. (1972), ‘On total, matric <strong>an</strong>d osmotic suction’, Soil Science 114(5), 339–348. Kumbhojkar, A. S. (1993), ‘Numerical evaluation <strong>of</strong> Terzaghi’s N (gamma)’, Journal <strong>of</strong> Geotechnical Engineering 119(3), 598–607. Kunze, R. J., Uehara, G. & Graham, K. (1968), ‘Factors import<strong>an</strong>t in the calculation <strong>of</strong> hydraulic conductivity’, Soil Science Society <strong>of</strong> America Journal 32, 760–765. Ladd, R. S. (1974), ‘Specimen preparation <strong>an</strong>d liquefaction <strong>of</strong> s<strong>an</strong>ds’, Journal <strong>of</strong> Geotechnical Engineering Division, ASCE 100(10), 118–184. Ladd, R. S. (1978), ‘Preparing test specimens using undercompaction’, Geotechnical Testing Journal 1(1), 16–23. Lambe, T. W. & Whitm<strong>an</strong>, R. V. (1969), Soil mech<strong>an</strong>ics, New York, Wiley. Lawton, E. C., Fragaszy, R. J. & Hardcastle, J. H. (1989), ‘Collapse <strong>of</strong> compacted clayey s<strong>an</strong>d’, Journal <strong>of</strong> Geotechnical Engineering 115(9), 1252–1267. Lawton, E. C., Fragaszy, R. J. & Hardcastle, J. H. (1991), ‘Stress ratio effects on collapse <strong>of</strong> compacted clayey s<strong>an</strong>d’, Jounral <strong>of</strong> Geotechnical Engineering 117(5), 714–730. Lawton, E. C., Fragaszy, R. J. & Hetherington, M. D. (1991), Signific<strong>an</strong>ce <strong>an</strong>d control <strong>of</strong> wetting-induced collapse in compacted soils, Technical Report 91-01, University <strong>of</strong> Utah, Salt Lake City, Utah.
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