S. Dent-glasser, N. Kataoka-]-r, F. Dron, . Brivot-]-t, M. Ichikawa et al., The chemistry of alkali-aggregate reaction, Cement and 526 Concrete Research Thermodynamic and kinetic approach to the alkali-silica reaction. 528 Part 2: Experiment, Cement and Concrete Research Modified model of alkali-silica reaction Cement and Concrete 530 Research Alkali-silica reaction, pessimum effects and pozzolanic effect, Cement 532 and Concrete Research Cement-aggregate reaction 534 in concrete A study of alkali-silica reactivity by means 537 of mortar bar expansions, Journal of the American Concrete Institute, Proceedings Journal of the American Concrete Institute, Proceedings Thaulow, A study of expansion due to alkali-silica reaction as 540 conditioned by the grain size of the reactive aggregate, Cement and Concrete Research] S. Sprung, Influence of the alkali-aggregate reaction in concrete, Symposium on 543, pp.55-56, 1947.

D. W. Hobbs and W. Gutteridge, Particle size of aggregate and its influence upon the 546 expansion caused by the alkali-silica reaction, Magazine of Concrete research, State Cement Works Alkali aggregate reaction with opaline sandstone, 7 th 549 International Congress on the Chemistry of Cement, pp.231-244, 1975.

M. Kawamura, K. Takemoto, and S. Hasaba, Application of quantitative EDXA analyses 552 and microhardness measurements to the study of alkali-silica reaction mechanisms, 6 th 553 International Conference of Alkalis in Concrete, Idorn G.M. and Rostam S, vol.3, issue.555, pp.167-174, 1983.

]. X. Zhang and G. W. Groves, The alkali-silica reaction in OPC-silica glass mortar with 560 particular reference to pessimum effects Influence of aggregate size and 562 aggregate size grading on ASR expansion, Materials Science to Construction Materials Engineering, 1 st International RILEM Congress 558 on Durability of Construction Materials, pp.919-926, 1987.

T. Kuroda, S. Nishibayashi, S. Inoue, A. Yoshino, ]. Y. Shao et al., Effects of the particle size of 570 reactive fine aggregate and accelerated test conditions on ASR expansion of mortar bar Studies on concrete containing ground 573 waste glass, Cement and Concrete Research Effects of particle size, grading and 575 content of reactive aggregate on ASR expansion of mortars subjected to autoclave method Andic, Effects of aggregate size and angularity on alkali? 579 silica reaction, Activated Fly Ash and Portland Cement Mortars, Journal of Materials in Civil Engineering 571 Transactions of the Japan Concrete Institute 576 12 th International Conference on Alkali-Aggregate Reaction in Concrete, Tang M. and Deng 577 M Cyr, E. Ringot, A. Carles-Gibergues, Efficiency of reactive aggregate 581 powder in controlling the expansion of concrete affected by alkali-silica reaction (ASR), pp.568-67, 2000.

S. Multon, M. Cyr, A. Sellier, N. Leklou, L. Petit-]-s et al., Coupled effects of aggregate size 585 and alkali content on ASR expansion, Cement and Concrete Research Effect of aggregate size and 587 alkali content on ASR expansion Effects of aggregate size on alkali?silica-reaction 589 induced expansion The influence of test specimen dimensions on the expansion of reactive 591 alkali aggregate in concrete Influence of dimension of test specimen on 594 alkali aggregate reactive expansion Effect of the cement chemistry and the sample size on 596 ASR expansion of concrete exposed to salt Influence of specimen 599 geometry, direction of casting, and mode of concrete consolidation on expansion due to ASR. 600 Cement, International Conference on Alkali-Aggregate Reaction in Concrete Proceedings of the 6th ICAAR Mechanical predictions on concrete deterioration. part 1: Eigenstresses 602 in concrete, ACI Materials Journal Mathematical model for kinetics of alkali-silica reaction in 604 concrete, Cement and Concrete Research, pp.617-624, 1983.

]. C. Dunant, K. L. Scrivener-furusawa, H. Ohga, and T. U. Malhotra, Micro-mechanical modelling of alkali?silica-reaction 610 induced degradation using the AMIE framework An analytical study concerning prediction of 613 concrete expansion due to alkali-silica reaction Chemo?mechanical modeling for prediction of alkali 616 silica reaction (ASR) expansion, Cement and Concrete Research Chemical modelling of Alkali Silica reaction: Influence of the reactive aggregate size 619 distribution, Application to the alkali-silica reaction, Computational Material Science Thogersen, Development of stresses in concrete structures 621 with alkali-silica reactions, Material and Structures37] A. Sellier, J-P. Bournazel, A. Mébarki, Modelling the alkali aggregate reaction within a 623 probabilistic frame-work, 10 th International Conference of Alkali Aggregate Reaction, pp.1163-608, 1993.

A. A. Melbourne, W. Suwito, Y. Jin, C. Xi, . A. Meyer et al., Une modélisation de l'alcali-réaction intégrant 628 une description des phénomènes aléatoires locaux A computational linear elastic fracture mechanics-based 631 model for alkali?silica reaction A fracture mechanics approach to the crack formation in 633 alkali-sensitive grains, Cement and Concrete Research Optimising an expansion test for the 635 assessment of alkali-silica reaction in concrete structures Contribution to the requalification of Alkali Silica Reaction (ASR) 638 damaged structures: Assessment of the ASR advancement in aggregates Comportement mécanique des matériaux : 643 viscoplasticité, endommagement, mécanique de la rupture, mécanique du contact, Hermes 644 Eds Mechanism of damage for the alkali? 648 silica reaction Relation of expansion due to 650 alkali silica reaction to the degree of reaction measured by SEM image analysis, Cement and 651, ASR in concrete, Concrete Science and Engineering Constitutive model for alkali-aggregate reactions, ACI 646 Materials Journal Deleterious alkali?silica reactivity in the laboratory and under field 653 conditions, Magazine of Concrete Research Reduction in Mortar and Concrete Expansion with 655, pp.694-701, 1988.

M. H. Shehata, M. D. Thomas-]-m, B. Q. Thomas, P. J. Blackwell, S. Nixon et al., The effect of fly ash composition on the expansion of 658 concrete due to alkali?silica reaction Estimating the alkali contribution from fly 661 ash to expansion due to alkali-aggregate reaction in concrete, Magazine of Concrete Research Diffusion of ions through hardened cement pastes Cement and 664 Concrete Research The percolation of pore space in the cement 667 paste/aggregate interfacial zone of concrete The interfacial transition zone (ITZ) 670 between cement paste and aggregate in concrete, Reactive Aggregates Due To Alkali Leaching, Cement, Concrete and Aggregates Combination of structural 672 monitoring and laboratory tests for the assessment of AAR-swelling: application to a gate 673 structure dam, pp.42-49, 1981.