Separations for the nuclear fuel cycle in the 21st century

This book constitutes the proceedings from a symposium titled Separations for the Nuclear Fuel Cycle in the 21st Century which was held in March 2004. This symposium focused on assessing the current state-of-the art in nuclear separations science and technology, and on identifying R&D directions required to enable nuclear separations to meet 21st Century demands for waste minimization, environment protection, safety, and security. Several recent developments have elevated the importance of this topic including: the potential effects of global warming caused by carbon dioxide emissions from burning of fossil fuels; rising demand for the electric power that is needed to raise the global standard of living; geopolitical issues such as those related to nuclear proliferation and nuclear terrorism. Although expansion of fission-based nuclear power would help reduce the potential for global warming, future development of the nuclear fuel cycle must be weighed against the issues of proliferation and management of irradiated fuel. Separations will play a central role in addressing these issues. The subject matter of this book is organized into five topical areas. These are: 1) current trends and direction to the future, 2) aqueous processing, 3) emerging separations systems, 4) actinide/lanthanide separations, and 5) solution-solid interactions. This collection of papers provides a snapshot of the current state of nuclear separations chemistry and can be used to help guide future directions in this critical technological field.

• Current Trends and Direction to the Future
• 1. Significance of the Nuclear Fuel Cycle in the 21st Century
• 2. Twenty-first Century Approaches to Actinide Partitioning
• 3. Advanced Separation Technologies for Processing Spent Nuclear Fuel and the Potential Benefits to a Geologic Repository
• 4. Reprocessing Spent Nuclear Fuel with Supercritical Carbon Dioxide
• Aqueous Processing
• 5. Dissolution of Irradiated Nuclear Fuel from the Big Rock Point Reactor
• 6. Advanced PUREX Flowsheets for Future Np and Pu Fuel Cycle Cemands
• 7. Haze Formation and Behavior in Liquid-Liquid Extraction Processes
• 8. Comparison of Uranyl Third Phase Formation in 30% TBP/Nitric Acid in Dodecane and HPT Using UV-Visible Spectroscopy
• 9. A New Interpretation of Third Phase Formation in the Solvent Extraction of Actinides by TBP
• 10. The Interaction of Ammonium Carbamate with Uranyl and Molybdenum Containing Species Derived from PUREX Processing
• 11. Plutonium Peroxide
• 12. Crystallization of Uranium Complexes for Partitioning of Spent Nuclear Fuel
• Emerging Separations Systems
• 13. Potential Application of Klaui Ligands in Actinide Separations
• 14. Actinide, Lanthanide and Fission Product Speciation and Electrochemistry in Ionic Melts
• 15. Application of Ionic Liquids in Actinide and Fission Product Separations: Progress and Prospects
• Actinide/Lanthanide Separations
• 16. Use of Cyanex-301 for Separation of Am/Cm From Lanthanides in an Advanced Nuclear Fuel Cycle
• 17. Extraction Separation of Am(III) and Eu(III) with TPEN Isomers and Decanoic Acid
• Solution-Solid Interactions
• 18. The Influence of Simple Erganic Ligands on the Partitioning Mechanism of Trivalent Lanthanum to Goethite
• 19. Neptunium Association with Selected Uranyl Phases Anticipated in the Yucca Mountain Repository
• 20. Speciation and Solubility Modeling of Actinides in the Waste Isolation Pilot Plant