BIBLIOGRAPHIE [117] K. L. Scrivener. Backsctattered electron imaging of cementitious microstructures : understanding and quantification. Cement and Concrete Composites, 26 :935–945, 2004. [118] T. C. Hansen. Physical structure of hardened cement paste. With classical approach. Mater. Construct. (RILEM), 114 :423–436, 1986. [119] Y. Xi, Z. P. Baˇzant, H. M. Jennings. Moisture diffusion in cementitious materials : part i & ii. Advanced Cement Based Materials, 2 :258–266, 1994. [120] J. M. Torrenti, L. Granger, M. Diruy, P. Genin. Modélisation du retrait du béton en ambiance variable. Revue Française de Génie Civil, 1[4] :687–698, 1997. [121] T. C. Powers, T. L. Brownyard. Studies of the physical properties of hardened Portland cement paste. Journal of the American Concrete Institute, 18 :101–132, 1946-1947. [122] R. H. Mills. Factors influencing cessation of hydration in water cured cement pastes. ACI-SP, 60 :406–424, 1966. [123] L. J. Parrott, M. Geiker, W. A. Gutteridge, D. Kikkoh. Monitoring Portland cement hydration : comparison of methods. Cement and Concrete Research, 20[6] :919–926, 1990. [124] H. Justnes, I. Meland, J. O. Bjoergum, J. Krane. The mechanism of silica fume action in concrete studied by solid state 29 Si NMR. NMR Seminar, Guerville, France, 1992 (cité par Waller 1999). [125] H. Justnes, E. J. Sellevold, G. Lundevall. High strengh concrete binders - Part A : Composition of cement pastes with, and without condensed silica fume. 4th CANMET/ACI International Conference on Fly Ash, Silica Fume, Slag and Natural Pozzolans in Concrete, Istanbul, V.M Malhorta Ed., 2SP132-47, 1992 (cité par Waller 1999). [126] O. Coussy. Mechanics of Porous Continua, John Wiley & Sons, Chichester, U.K, 1995. [127] B. A. Schrefler, W. G. Gray. Thermodynamic approach to effective stress in partially saturated porous media. European Journal of Mechanics, A/Solids, 20 :521–538, 2001. [128] M. A. Biot. General theory of three-dimensional consolidation. Journal of Applied Physics, 12 :155–164, 1941. [129] Z. P. Baˇzant, S. Prasannan. Solidification theory for concrete creep. i Formulation - ii Verification and application. Journal of Engineering Mechanics, 115[8] :1691–1725, 1989. [130] G. De Schutter, L. Taerwe. Towards a more fundamental non-linear basic creep model for early-age concrete. Magazine of Concrete Research, 49[180] :195–200, 1997. [131] L. Dormieux. Poroelasticity and strength of fully or partially saturated porous materials. Dans : Applied micromechanics of porous materials, L. Dormieux and F. J. Ulm (Eds) CISM Courses and Lectures 480, SpringerWienNewYork, 109–152, 2005. [132] J. Zreiki, V. Lamour, M. Moranville, M. Chaouche. Détermination <strong>des</strong> contraintes mécaniques dans les pièces massives en béton au jeune âge : instrumentation in-situ et modélisation. Proceeding, 8ème édition <strong>des</strong> Journées scientifiques du Regroupement francophone pour la recherche et la formation sur le béton (RF) 2 B, Montréal, Canada, 2007. [133] H. F. W. Taylor. Modification of the Bogue calculation. Advan. Cem. Res., 2[6] :71–77, 1989. [134] O. Bonneau. Etude <strong>des</strong> effets physico-chimiques <strong>des</strong> superplastifiants en vue d’optimiser le comportement rhéologique <strong>des</strong> bétons à ultra hautes performances. Thèse de doctorat, Ecole Normale Supérieure de Cachan - Université de Sherbrooke, 135p., 1997. 152
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