250 BIBLIOGRAPHY Ferré, P. A. & Topp, G. C. (2002), Time domain reflectometry, in J. H. D<strong>an</strong>e & G. C. Topp, eds, ‘Methods <strong>of</strong> soil <strong>an</strong>alysis. Part 4: Physical Methods’, SSSA Book Series No. 5, Soil Science Society <strong>of</strong> America, Madison, WI, pp. 434–446. Finn, W. D. L., Pickering, D. J. & Br<strong>an</strong>sby, P. L. (1971), ‘S<strong>an</strong>d liquifaction in triaxial <strong>an</strong>d simple shear tests’, Journal <strong>of</strong> the Soil Mech<strong>an</strong>ics <strong>an</strong>d Foundations Division 97, 639–659. Flavigny, E., Desrues, J. & Palayer, B. (1990), ‘Note technique: Le sable d’hostun rf’, Revue Fr<strong>an</strong>çaise de Géotechnique 53, 67–70. Fredlund, D. G. (1973), ‘Second c<strong>an</strong>adi<strong>an</strong> geotechnical colloqium: Appropriate concepts <strong>an</strong>d technology for unsaturated soils’, C<strong>an</strong>adi<strong>an</strong> Geotechnical Journal 16(1), 121–139. Fredlund, D. G. (2002), Use <strong>of</strong> the soil-water characteristic curvein the implementation <strong>of</strong> unsaturated soil mech<strong>an</strong>ics, in ‘3rd Int. Conf. on <strong>Unsaturated</strong> Soils, UNSAT 2002’, Balkema, Recife, Brazil, pp. 887–902. Fredlund, D. G. & Morgenstern, N. R. (1977), ‘Stress state variables for unsaturated soils’, Journal <strong>of</strong> the Geotechnical Engineering Division 5(103), 447–466. Fredlund, D. G., Morgenstern, N. R. & Widger, R. A. (1978), ‘The shear strength <strong>of</strong> unsatu- rated soils’, C<strong>an</strong>adi<strong>an</strong> Geotechnical Journal 15, 313–321. Fredlund, D. G. & Rahardjo, H. (1993a), The role <strong>of</strong> unsaturated soil behavior in geotechnical practice, in ‘11th Southeast Asi<strong>an</strong> Geotechnical Conference’, Singapore, pp. 37–49. Fredlund, D. G. & Rahardjo, H. (1993b), Soil mech<strong>an</strong>ics for unsaturated soils, John Wiley <strong>an</strong>d Sons, New York. Fredlund, D. G., Rahardjo, H., Leong, E. C. & Ng, C. W. W. N. (2001), Suggestions <strong>an</strong>d recommendation for the interpretation <strong>of</strong> soil-water characteristic curves, in K. K. Ho & K. S. Li, eds, ‘14th Southeast Asi<strong>an</strong> Geotechnical Conference’, Hongkong, pp. 1–6. Fredlund, D. G. & Xing, A. (1994), ‘Equations for soil-water characteristic curve’, C<strong>an</strong>adi<strong>an</strong> Geotechnical Journal 31, 521–532. Fredlund, D. G., Xing, A., Fredlund, M. D. & Barbour, S. L. (1996a), ‘The relationship <strong>of</strong> the unsaturated soil shear strength to the soil-water characteristic curve’, C<strong>an</strong>adi<strong>an</strong> Geotechnical Journal 33, 440–448. Fredlund, D. G., Xing, A., Fredlund, M. D. & Barbour, S. L. (1996b), ‘The relationship <strong>of</strong> the unsaturated soil shear strength to the soil-water characteristic curve’, C<strong>an</strong>adi<strong>an</strong> Geotechnical Journal 33, 440–448.
BIBLIOGRAPHY 251 Fredlund, D. G., Xing, A. & Hu<strong>an</strong>g, S. (1994), ‘Predicting the permeability function for unsaturated soils using the soil-water characteristic curve’, C<strong>an</strong>adi<strong>an</strong> Geotechnical Journal 31, 533–546. Fredlund, M. D., Fredlund, D. G. & Wilson, G. W. (1997), Prediction <strong>of</strong> the soil-water char- acteristic curve from grain-size distribution <strong>an</strong>d volume-mass properties, in ‘Proceedings <strong>of</strong> the 3rd Brazili<strong>an</strong> Symposium on <strong>Unsaturated</strong> Soils, Vol. 1’, Rio de J<strong>an</strong>eiro, pp. 13–23. Fredlund, M. D., Fredlund, D. G. & Wilson, G. W. (2000), ‘An equation to represent grain-size distribution’, C<strong>an</strong>adi<strong>an</strong> Geotechnical Journal 37, 817–827. Frost, J. D. & Park, J.-Y. (2003), ‘A critical assessment <strong>of</strong> the moist tamping technique’, Geotechnical Testing Journal 26(1), 1–13. Fujimaki, H. & Inoue, M. (2003), ‘Reevaluation <strong>of</strong> the multistep outflow method for deter- mining unsaturated hydraulic conductivity’, Vadose Zone Journal 2, 409—415. Fung, Y. C. (1977), A first course in continuum mech<strong>an</strong>ics, 2nd edn, Englewood Cliffs, NJ: Princton-Hall. G<strong>an</strong>, J. K. M., Fredlund, D. G. & Rahardjo, H. (1988), ‘Determination <strong>of</strong> the shear strength parameters <strong>of</strong> <strong>an</strong> unsaturated soil using the direct shear test’, C<strong>an</strong>adi<strong>an</strong> Geotechnical Jour- nal 25, 500–510. Gardner, C. M. K., Robinson, D., Blyth, K. & Cooper, D. (2001), Soil water content, in K. A. Smith & C. E. Mullins, eds, ‘Soil <strong>an</strong>d environmental <strong>an</strong>alysis: Physical Methods’, Marcel Dekker, New York, NY, pp. 1–64. Gardner, W. (1956), ‘Calculation <strong>of</strong> capillary conductivity from pressure plate outflow data’, Soil Science Society <strong>of</strong> America Journal 20, 317–320. Gardner, W. R. (1958), ‘Some staedy state solutions <strong>of</strong> the unsaturated moisture flow equation with application to evaporation from a water table’, Soil Science 85, 228–232. Gee, G., Campbell, M., Campbell, G. & Campbell, J. (1992), ‘Rapid measurement <strong>of</strong> low soil potentials using a water activity meter’, Soil Science Society <strong>of</strong> America Journal 56, 1068– 1070. Gennaro, V. D., C<strong>an</strong>ou, J., Dupla, J. C. & Benahmed, N. (2004), ‘Influence <strong>of</strong> loading path on the undrained behavior <strong>of</strong> a medium s<strong>an</strong>d’, C<strong>an</strong>adi<strong>an</strong> Geotechnical Journal 41, 166–180. Gens, A. & Alonso, E. E. (1992), ‘A framework for the behaviour <strong>of</strong> unsaturated exp<strong>an</strong>sive clay’, C<strong>an</strong>adi<strong>an</strong> Geotechnical Journal 29, 1013–1032. Gilbert, P. A. & Marcuson, W. F. (1988), ‘Density variation in specimens subjected to cyclic <strong>an</strong>d monotonic loading’, Journal <strong>of</strong> Geotechnical Engineering Division 114(1), 1–20.
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