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[3] Hauser, W. Geckeis, H., Götz, R., Noseck, U., Laciok, A. (2005). Colloid Detection in Natural Ground Water from Ruprechtov by Laser-Induced Breakdown Detection. [4] Noseck, U., Brasser, Th., Suksi, J., Havlova, V., Hercik, M., Denecke, M.A., Förster, H.J., (2008). Identification of uranium enrichment scenarios by multi-method characterisation of immobile uranium phases. J. Phys. Chem. Earth, doi:10.1016/j.pce.2008.05.018. [5] Cervinka, R., Havlova, V.; Noseck, U.; Brasser, Th.; Stamberg, K., (2007). Characterisation of organic matter and natural humic substances extracted from real clay environment. Annual Workshop Proceedings of the IP Project FUNMIG”. Edinburgh 26.-29.November 2007. [6] Denecke, M.A., Janssens, K., Proost, K., Rothe, J., Noseck, U., (2005). Confocal micro-XRF and micro-XAFS studies of uranium speciation in a Tertiary sediment from a waste disposal natural analogue site. Environ. Sci. Technol. 39(7), 2049-2058. [7] Denecke, M.A., Somogyi, A., Janssens, K., Simon, R., Dardenne, K., Noseck, U., (2007). Microanalysis (micro-XRF, micro-XANES and micro-XRD) of a Tertiary sediment using synchrotron radiation. Microscopy Microanal. 13(3), 165-172. [8] Ervanne, H., Suksi, J., (1996). Comparison of Ion-Exchange and Coprecipitation Methods in Determining Uranium Oxidation States in Solid Phases. Radiochemistry 38, 324-327. [9] Havlová, V., Laciok, A.; Vopálka, D.; Andrlík, M. (2006): Geochemical Study of Uranium Mobility in Tertiary Argillaceous System at Ruprechtov Site, Czech Republic. Czechoslovak Journal of Physics, Vol. 56, Suppl. D, 1-6. [10] Noseck, U., Brasser, Th., 2006. Radionuclide transport and retention in natural rock formations – Ruprechtov site. Gesellschaft für Anlagen- und Reaktorsicherheit, GRS-218, Köln. [11] Buckau, G., Artinger, R., Geyer, S., Wolf, M., Fritz, P., Kim, J.I., (2000). Groundwater in-situ generation of aquatic humic and fulvic acids and the mineralization of sedimentary organic carbon. Appl. Geochem. 15, 819-832. [12] Knöller, K., Fauville, A., Mayer, B., Strauch, G., Friese, K., Veizer, J., (2004). Sulfur cycling in an acid mining lake and its vicinity in Lusatia, Germany. Chem. Geol. 204, 303-323. [13] Vopalka, D., Havlova, V., Andrlik, M. (2008): Characterization of U(VI) behaviour in the Ruprechtov site (CZ). Proc. of the International Conference Uranium Mining and Hydrogeology V, Freiberg, September, 14.-18. 2008. [14] Bethke, C.M., (2006): The Geochemist’s Workbench Release 6.0. Hydrogeology Program, University of Illinois. [15] Yoshida, Y., Shibata M., (2004): Establishment of Data Base Files of Thermodynamic Data developed by OECD/NEA Part II - Thermodynamic data of Tc, U, Np, Pu and Am with auxiliary species. JNC Technical Report, JNC TN8400 2004-025. 352
Radionuclide Migration in the Far-Field: The Use of Research Results in Safety Cases Bernhard Schwyn 1 , Jürg Schneider 1 , Jörg Rüedi 1 , Jesus Alonso 2 , Scott Altmann 3 , Stephane Brassinnes 4 , José Luis Cormenzana López 2 , Aimo Hautojärvi 5 , Jan Marivoet 6 , Ignasi Puigdomenech 7 , André Ruebel 8 , Cherry Tweed 9 , Tiziana Missana 10 , Ulrich Noseck 8 , Pascal Reiller 11 , Thorsten Schäfer 12 Summary 1 NAGRA, Switzerland, 2 ENRESA, Spain 3 ANDRA, France 4 ONDRAF/NIRAS, Belgium, 5 POSIVA, Finland, 6 SCK•CEN, Belgium 7 SKB, Sweden, 8 GRS, Germany, 9 NDA, UK 10 CIEMAT, Spain, 11 CEA, France, 12 FZK, Germany In the Integrated Project FUNMIG fundamental processes governing radionuclide migration in the geosphere were investigated. Within the RTD Component 6 the involved Waste Management Organisations (WMOs) and an Integration Monitoring Group coordinated the linking of the scientific work performed in the Components 1 to 5 to its use in performance assessment and monitored the improvements achieved within this project for the safety cases of the individual radioactive waste disposal programmes in Europe. Boundary conditions for the near-field of a radioactive waste repository, in particular radionuclide fluxes and concentrations but also repository induced perturbations of the geosphere, were defined based on the WMOs’ safety cases and on the outcome of the European Project NF-PRO. A comprehensive catalogue providing concise information for each task performed in FUNMIG was compiled. It facilitates the retrieval of knowledge acquired within FUNMIG and was used to map these tasks to internationally accepted lists of Features, Events and Processes (FEPs) for clay-rich, crystalline and salt host rocks. The subsequent evaluation revealed issues important for future safety cases, namely the mechanistic understanding, quantification and up-scaling of radionuclide diffusion in clay-rich host rocks and, for crystalline host rocks, the influence of colloids on radionuclide transport and the up-scaling of reactive transport modelling in fractured systems. Finally, the scientific outcome of FUNMIG was synthesised for each of the three host rocks by collecting the individual tasks in Super-FEPs. The transferability of knowledge between the host rocks is limited due to the host rock and site specificity of the research performed in FUNMIG. 1. Introduction The scope of the Integrated Project FUNMIG was to improve and supplement the scientific knowledge on radionuclide migration in host rocks for future safety cases for the various European radioactive waste disposal programmes. In the compilation of a safety case several groups are involved. E.g., in developing the safety case for the Project Opalinus Clay [1] four groups, each with welldefined roles, were distinguished: The management group, responsible for overall management of repository planning. 353
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Interested in European research? Re
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LEGAL NOTICE Neither the European C
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TABLE OF CONTENTS FOREWORD iii CONF
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“Impact of advanced fuel cycle sc
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“Sensitivity analysis techniques
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Topic: Support actions SAPIERR-II -
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CONFERENCE SUMMARIES
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supported. The Commission believes
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Ms Monika Hammarström of SKB in Sw
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Dr Bruno of Amphos 21 urged the swi
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measurements of actinides to determ
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Dr Peter Blümling of Nagra in Swit
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Future directions There seemed to b
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1. Introduction Keynote Address Pet
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tive waste management, a considerab
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the decision making process. The se
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All initiatives leading to encourag
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tegrating them as part of advanced
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General introduction and objectives
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Radioactive waste management: Where
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The intense development in nuclear
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Figure 3: Schematic diagram of the
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contributed to enhance knowledge ab
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the first time in French history, a
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PANEL DISCUSSION Summary of the Pan
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With the support of IAEA preliminar
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Assessment of Financial Provisions
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collected in the cost of the nuclea
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erated by Fortum) and one PWR unit
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pected. As to tunnel backfilling, t
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ferent, the technological solutions
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Discussion: As a response to a ques
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Cooperation in the development of g
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During the 1980’s it was realized
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government on the operating license
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tions. EDRAM is another example of
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Discussion: The chairman opened the
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Communicating the safety of radioac
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Communicating the Safety of Radioac
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Geological repositories … Differe
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Geological long-term stability (pla
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Times & doses in perspective (examp
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Trust is generated (by the regulato
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4. The regulators could play a very
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Europe's nuclear industries, theref
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filled - one key example being coll
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Table 2. FP6 Integrated Projects an
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EUROTRANS focuses on the transmutat
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consensus that geological disposal
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102
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104
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significantly reduce the quantities
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Pyrochemical processes rely on refi
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Figure 3: Schematic layout of an el
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Considering pyrochemistry technolog
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agreed for support through an integ
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Table 1: Fuels irradiated in the SU
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lead cooling (see Fig. 5). Alternat
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Figure 6: Principle design characte
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Table 6: FUTURIX FTA fuels Fuel nam
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124
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After a review of the present statu
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suranium elements, “repository av
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nificant fraction of fast reactors.
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high level waste at the considered
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Pu or M.A. by the time it is needed
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of U and Pu only. P&T could complem
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suranium elements, the thermal load
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Phase-Out TRU Transmutation Scenari
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10 nuclear nations (Argentina, Braz
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elease, strong radiation, pressure
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A1 3.79E+08 270 7.12E-07 A2 3.51E+0
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nuclear fission in the reactors. Th
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5. Conclusions The HLW arising from
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152
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tinides (MA) are destined for geolo
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[3] Enrique González: Head of Nucl
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158
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160
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erage level of funding of research
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Prior to NF-PRO, the question wheth
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nant exchangeable cation. This chan
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eal concentration gradient in sampl
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access shafts, providing higher per
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172
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in the European coordinated action
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proved, with amongst others the det
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4. Discussion Tests with dissolved
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though with a slow rate. The data i
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surface. The coupling between water
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nuclear waste within the near-field
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tion of the column [2]. Moreover, t
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case, the iron diffusion front in t
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5.1 Sorption As an example of the t
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corrosion; up-scaling of clay alter
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Bentonite barriers are very importa
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To determine the impact of temperat
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in the underground laboratory in Gr
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under isothermal conditions. If the
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202
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Zones around such openings which ex
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layout of cells developed by ENPC w
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) a) e) d) f) d) e) f) c) Figure 3.
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EDZ removal by additional excavatio
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[7] Wenk H.-R., Voltolini, M., Mazu
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that provided by various national s
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system robustness, rather than as s
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Regarding diffusion studies perform
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7. EDZ characterization and evoluti
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[4] Alonso, J. et al. 2004: Bentoni
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There has been a significant change
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226
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228
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2. Methodology ESDRED has been focu
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Figure 3: Reduced scale mock-up aft
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Figure 8: Demonstration of emplacem
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The various reports produced by the
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238
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2. Methodology In general, the work
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limitations of the selected press.
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Figure 3.2.1 Schematic representati
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which was relatively homogeneous in
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Figure 3.3.1 Emplacement of SF-Cani
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1.650 1.600 1.550 1.500 1.450 1.400
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the outlet with some pressure and f
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A experiment, using cross-hole seis
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This seal will be implemented as ri
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[6] Miehe, R., Kröhn, P., Moog, H.
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dence. For waste canister transport
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The main waste canister characteris
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placement borehole. The BSK 3 canis
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Figure 6: Sketch of the Pushing Rob
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268
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1.1 Water Cushion Application SKB (
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In the case of SKB and Posiva, the
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Deposition machine tests with load
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Figure 10: Details of electrical pu
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the very heavy weight (43 ton) of t
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is no experience in either the work
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the case of the long plug elaborate
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values measured in the percolated w
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plug the concrete was mixed manuall
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2.3 Testing of low-pH shotcrete for
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290
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energy is produced by fission of ur
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3.2. Integration 3.2.1. Pool Facili
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3.4. Education and Training Apart f
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298
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Fig. 1.1: EU Member States involved
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Page 320 and 321: - Present state of scientific level
Page 322 and 323: 6. Training courses Key events of t
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Page 326 and 327: materials, the essential aspects of
Page 328 and 329: 2.1 Geological formation scale (10
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Page 344 and 345: ganic/organic colloids”; WP 4.5
Page 346 and 347: Figure 1: Schematic of the FEBEX dr
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Page 350 and 351: Colloid Concentration (ppm) 160 140
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Page 354 and 355: References [1] Retrock (2005). Trea
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Page 372 and 373: FEPCAT RTDC 1 RTDC 2 RTDC 3 Clay-ri
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Page 386 and 387: The main goal of RTDC-1 is to provi
Page 388 and 389: 3. RTDC3 In RTD component 3 methodo
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Page 396 and 397: A simplistic summary might place PA
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Page 400 and 401: 10-11 June 2008. The workshop was a
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Page 408 and 409: 2.2.3 Graphical methods Let us call
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Page 416 and 417: 2. Methodology The project particip
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Closely related to this proposal on
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4.3 Structure The TP structure must
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4.5 Implementation It is proposed t
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5.1 The CARD Project has shown that
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� What steps should be taken to m
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412
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414
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materials. For attaining the stated
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the bottom of the heated press-mold
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420
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422
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focuses on the study of the combine
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emitting radioactive waste to study
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428
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2.1 Laboratory experiment The dispo
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3. Results 3.1 Laboratory experimen
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Barrier. Clays in Natural & Enginee
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2. Experimental data 2.1 Laboratory
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sented in the accompanying poster,
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440
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situ stress to model the gallery ex
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tive crack network, oriented along
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446
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ous reasons, SCK•CEN chose to foc
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lery, are already monitoring temper
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[1] Bernier F., Li X.L., Weetjens E
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Concrete The cement used is an Ordi
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Brucite Ettringite 10 �m 8 �m F
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458
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2. Methodology In the case of cylin
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cell dismantled after 6 months, roo
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[3] G.E. Gdowski, Humid Air Corrosi
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crucial to predict the hydration ra
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load is higher, since the load appl
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[4] Gens, A. & Alonso, E. 1992. A f
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2. Experimental Methodology A salt
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proof of healing in salt rocks. It
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476
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obtained experimental results [1].
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dependent shear strength softening
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482
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elease falls typically between 1 an
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Figure 3: Left: Spent fuel surface
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488
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1. Data compilation and evaluation
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Volumetric deformation [%] 20 18 16
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An overview of the test procedure w
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496
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The works performed within RTDC-1 p
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Integrated Project “Fundamental P
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502
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The Ruprechtov natural analogue sit
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esults and integrated to develop a
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508
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510
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from 12.5 to 13.5, have high ionic
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elative intensity (cps) 8000 6000 4
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516
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518
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2. SAPIERR I and II In Europe, the
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after extensive interactions have t
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eing partners if an ERDO is formall
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526
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2. Methodology Based on existing da
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external funds ensuring the indepen
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532
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534
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Mr Jozef BALAZ JAVYS, a.s. - Nuclea
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Prof. Gunnar Johan BUCKAU Forschung
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Dr Mario DIONISI APAT - Dipartiment
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Dr Paloma GÓMEZ GONZÁLEZ CIEMAT -
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Ms Aurélie JESTIN SOGEDEC Z.I. Dig
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Dr Patrick MAJERUS Ministry of Heal
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Mr Zoltán NAGY PURAM - Department
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Ms Katerina PTACKOVA European Commi
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Prof. Christian SCHRÖDER Universit
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Dr Ján TIMUL'ÁK DECOM Slovakia, s
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Dr. Eng. Shuichi YAMAMOTO Obayashi
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