Summary
Engineered barriers made up of bricks of compacted swelling clays are considered as potential barriers for the isolation of high activity nuclear waste at great depth. To better understand their coupled hydro-mechanical response, the microstructure of engineered barriers has been studied by various authors by using most often scanning electron microscope observations and mercury intrusion pore size distribution measurements (MIP). These studies confirmed that the microstructure of compacted bentonites was made up of aggregates with two classes of pores: inter-aggregates pores and intra-aggregate pores. Further investigation conducted by using X-Ray diffractometry at low angles conducted more recently provided deeper insight into the hydration mechanisms that occur during hydration. This paper presents some results obtained by various authors by using these techniques. It shows how the hydration mechanisms occurring at the level of the clay particles inside the aggregates help interpreting existing MIP data. Some conclusions about the water retention properties of compacted bentonites with or without swelling allowed are given. Some consequences on the water transfer properties of compacted bentonites are also drawn. In both cases, the clogging of inter-aggregate pores due to particle exfoliation has a significant effect.
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References
Agus SS, Schanz T (2005) Effect of shrinking and swelling on microstructures and fabric of a compacted bentonite-sand mixture, In: Proc Int Conf on Problematic Soils, Cyprus 2:543–550
Ahmed S, Lovell CW, Diamonds S (1974) Pore sizes and strength of compacted clay, ASCE J Geotechnical Eng 100:407–425
Aylmore LAG, Quirk JP (1962) The structural status of clay systems, In: Proc 9th Nat Conf on Clays and Clay Minerals. Pergamon, Oxford, pp 104–130
Barden L, Sides GR (1970) Engineering behaviour and structure of compacted clay, ASCE J Soil Mech Found Div 96:1171–1200
Ben Rhaïem H, Pons CH, Tessier D (1985) Factors affecting the microstructure of smectites: role of cations and history of applied stresses, In: Schultz et al. (eds) Proc Int Clay Conf, Denver, The Clay Mineralogical Soc, pp 292–297
Bird P (1984) Hydration phase diagrams and friction of montmorillonite under laboratory and geologic conditions with implications for shale compaction, slope stability and strength of fault gauge, Tectonophysics 107:235–260
Bolt GH (1956) Physico-chemical analysis of the compressibility of pure clays, Géotechnique 6:86–93
Calvet R (1972) Adsorption de l’eau sur les argiles; Etude de l’hydratation de la montmorillonite, Bull Soc Chimique de France 8:3097–3104
Cui YJ, Loiseau C, Delage P (2002) Microstructure changes of a confined swelling soil due to suction controlled hydration, In: Proc 3rd Int Conf on Unsaturated Soils, UNSAT’2002. Recife, Brazil, Balkema 2:593–598
Collins K, McGown A (1974) The form and function of microfabric features in a variety of natural soils, Géotechnique 24(2):233–254
Delage P, Pellerin FM (1984) Influence de la lyophilisation sur la structure d’une argile sensible du Qu’ebec, Clay Minerals 19:151–160
Delage P, Tessier D, Marcel-Audiguier M (1982) Use of the Cryoscan apparatus for observation of freeze-fractured planes of a sensitive Quebec clay in scanning electron microscopy, Can Geotech J 19(1):111–114
Delage P, Audiguier M, Cui YJ, Howat MD (1996) Microstructure of a compacted silt, Can Geotech J 33:150–158
Delage P, Graham J (1995) The mechanical behaviour of unsaturated soils, In: Alonso EE, Delage P (eds) Proc 1st Int Conf on Unsaturated soils Paris, Balkema 3:1223–1256
Delage P, Lefebvre G (1984) Study of the structure of a sensitive Champlain clay and its evolution during consolidation, Can Geotech J 21(1):21–35
Delage P, Howat M, Cui YJ (1998) The relationship between suction and swelling properties in a heavily compacted unsaturated clay, Eng Geology 50(1–2):31–48
Delage P, Marcial D, Cui YJ, Ruiz X (2006) Ageing effects in a compacted bentonite: a microstructure approach, Géotechnique 56(5):291–304
Delvaux B, Tessier D, Herbillon A, Burtin G, Jaunet AM, Vielvoye L (1992) Morphology, texture and microstructure of halloysiticsoil clays as related to weathering and exchangeable cations, Clays and Clay Min 40(4):446–456
Diamond S (1970) Pore size distribution in clays, Clays and Clay Min 18:7–23
Diamond S (1971) Microstructure and pore structure of impact compacted clays, Clays and Clay Minerals 19:239–241
Fredlund DG, Rahardjo H (1993) Soil mechanics for unsaturated soils. Wiley, New-York
Gens A, Olivella S (2001) Clay barriers in radioactive waste disposal, Revue Française de Génie Civil 5(6):845–856
Gillott JE (1973) Methods of sample preparation for microstructureal analysis of soil, In: Soil Microscopy, Proc 4th Int Working Meeting on Soil Micromorphology, Kingston, pp 143–164
Komine H, Ogata N (1994) Experimental study on swelling characteristics of compacted bentonites, Can Geotech J 31:478–490
Lambe TW (1958) The structure of compacted soil, J Soil Mech Found Div 84(SM2):1–34
Loiseau C, Cui YJ, Delage P (2002) The gradient effect on the water flow through a compacted swelling soil, In: Proc. 3rd Int Conf Unsaturated Soils, UNSAT’2002 Recife, Brazil, Balkema 1:395–400
Lloret A, Villar MV, Sanchez M, Gens A, Pintado X, Alonso EE (2003) Mechanical behaviour of heavily compacted bentonite under high suction changes, G’eotechnique 53(1):27–40
Marcial D (2003) Comportement hydrom’ecanique et microstructural des mat’eriaux de barri‘eres ouvrag’ees. PhD Thesis, Ecole des Ponts, Paris
Marcial D, Delage P, Cui YJ (2002) On the high stress compression of bentonites, Can Geotech J 39:1–9
Mitchell JK, Soga K (2005) Fundamentals of soil behaviour. John Wiley, New-York
Mooney RW, Keenan AC, Wood LA (1952) Adsorption of water vapor by montmorillonite. II. Effect of exchangeable ions and lattice swelling as measured from X-ray diffraction, J Amer Chem Soc 74:1371–1374
Nalezny CL, Li MC (1967) Effects of soil moisture and thixotropic hardening on the swell behaviour of compacted expansive soils, Highway Research Record No 209. Highway Research Board, Washington DC
Pons CH, Rousseaux F, Tchoubar D (1981) Utilisation du rayonnement synchrotron en diffusion aux petits angles pour l’’etude du gonflement des smectites, Clay Minerals 16:23–42
Prost R (1975) Interactions between adsorbed water molecules and the structure of clay minerals: hydration of smectites. In: Bailey SW (ed) Proc Int Clay Conf 1975: Mexico City, Mexico. Applied Pub, Wilmette IL:351–359
Romero E, Gens A, Lloret A (1999) Water permeability, water retention and microstructure of unsaturated compacted Boom clay, Eng Geology 54:117–127
Saiyouri N, Hicher PY, Tessier D (1998) Microstructural analysis of highly compacted clay swelling, In: Proc. 2nd Int Conf on Unsaturated Soils Academic publishers, Beijing, China 1:119–124
Saiyouri N, Hicher PY, Tessier D (2000) Microstructural approach and transfer water modelling in highly compacted unsaturated swelling clays, Mech Cohesive Frictional Mater 5:41–60
Saiyouri N, Tessier D, Hicher PY (2004) Experimental study of swelling in unsaturated compacted clays, Clay Minerals 39:469–479
Schanz T, Tripathy S (2005) Soil-water characteristic curves of clays from physico-chemical concepts, In: Proc Int Conf on Problematic Soils. Famagusta, Cyprus 1:219–228
Sposito G, Prost R (1982) Structure of water adsorbed on smectites, Chem Rev USA 82:552–573
Sridharan A, Altschaeffl AG, Diamond S (1971) Pore size distribution studies, ASCE J of the Soil Mech Found Div 97:771–787
Sridharan A, Jayadeva MS (1982) Double layer theory and compressibility of clays,Géotechnique 32(2):133–144
Tessier D (1990) In: Decarreau A (ed) Mat’eriaux Argileux, Structure, Propri’et’es et Applications. Soc. Fr. Minéralogie et Cristallographie, Paris, France 1:387–445
Tovey NK, Wong KY (1973) The preparation of soils and other geological materials for the scanning electron microscope, In: Proc Int Symp on Soil Structure, Gothenburg, Sweden, pp 176–183
Tripathy S, Sridharan A, Schanz T (2004) Swelling pressures of compacted bentonites from diffuse layer theory, Can Geotech J 41:437–450
Washburn EW (1921) A method of determining the distribution of pore sizes in a porous material, Proc of the National Academy of Science 7:115
Yahia-Aissa M, Delage P, Cui YJ (2001) In: Adachi, Fukue (eds) Suction-water relationship in swelling clays, Clay Science for Engineering, IS-Shizuoka Int Symp on Suction, Swelling, Permeability and Structure of Clays, Balkema, pp 65–68
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Delage, P. (2007). Microstructure Features in the Behaviour of Engineered Barriers for Nuclear Waste Disposal. In: Schanz, T. (eds) Experimental Unsaturated Soil Mechanics. Springer Proceedings in Physics, vol 112. Springer, Berlin, Heidelberg. https://doi.org/10.1007/3-540-69873-6_2
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DOI: https://doi.org/10.1007/3-540-69873-6_2
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