guest ::
| Home > Publications database > Characterisation and final disposal behaviour of thoria-based fuel kernels in aqueous phases |
| Home > Publications database > Characterisation and final disposal behaviour of thoria-based fuel kernels in aqueous phases |
| Dissertation / PhD Thesis/Book | PreJuSER-50677 |
2005
Forschungszentrum Jülich GmbH Zentralbibliothek, Verlag
Jülich
Please use a persistent id in citations: http://hdl.handle.net/2128/2551
Report No.: Juel-4180
Abstract: Two high-temperature reactors (AVR and THTR) operated in Germany have produced about 1 million spent fuel elements. The nuclear fuel in these reactors consists mainly of thorium-uranium mixed oxides, but also pure uranium dioxide and carbide fuels were tested. One of the possible solutions of utilising spent HTR fuel is the direct disposal in deep geological formations. Under such circumstances, the properties of fuel kernels, and especially their leaching behaviour in aqueous phases, have to be investigated for safety assessments of the final repository. In the present work, unirradiated ThO$_{2}$, Th$_{0.906}$,U$_{0.094}$)O$_{2}$, (Th$_{0.834}$,U$_{0.166}$)O$_{2}$ and UO$_{2}$ fuel kernels were investigated. The composition, crystal structure and surface of the kernels were investigated by traditional methods. Furthermore, a new method was developed for testing the mechanical properties of ceramic kernels. The method was successfully used for the examination of mechanical properties of oxide kernels and for monitoring their evolution during contact with aqueous phases.The leaching behaviour of horia-based oxide kernels and powders was investigated in repositoryrelevant salt solutions, as well as in artificial leachates. The influence of different experimental parameters on the kernel leaching stability was investigated. It was shown that thoria-based fuel kernels possess high chemical stability and are indifferent to presence of oxidative and radiolytic species in solution. The dissolution rate of thoria-based materials is typically several orders of magnitude lower than of conventional UO$_{2}$ fuel kernels. The life time of a single intact (Th,U)O$_{2}$ kernel under aggressive conditions of salt repository was estimated as about hundred thousand years. The importance of grain boundary quality on the leaching stability was demonstrated. Numerical Monte Carlo simulations were performed in order to explain the results of leaching experiments.
|
The record appears in these collections: |
PDF
Fulltext by OpenAccess repository