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- Getting to the Core of the NUCLEAR FUEL CYCLE
- Nuclear Fuel Cycle
- The Present Status of the Debate of the Use of Nuclear Power in Australia
- FY 2014 Volume 5
- INSIGHT Into Nuclear Decommissioning
- Characteristics of a Tokamak Fusion Neutron Source for Spent Nuclear Fuel Transmutation
- FISSION PRODUCTS in the SPENT Nucjljbak * from CZECH NUCLEAR POWER PLANTS
- March 2020 Advanced Public Forum Brief
- The Nuclear Power Dilemma—Between Perception and Reality
- Americium-241 Radioisotope Thermoelectric Generator Development for Space Applications
- Nuclear Spent Fuel Management Scenarios. Status and Assessment Report
- Office of Environmental Management: Establishing Strategic Partnerships
- Plutonium Recovery from Spent Fuel Reprocessing by Nuclear Fuel
- Spent Nuclear Fuel Assay Data for Isotopic Validation
- Spectral X-Ray Radiography for Safeguards at Nuclear Fuel Fabrication Facilities: a Feasibility Study
- Discovery That Nuclear Fission Produces Tritium
- D1.1 – Report on the Assessment of Tritium Term Sources And
- Evaluation of CO {Sub 2} Emission in the Life Cycle of Tokamak Fusion
- Advanced LWR Nuclear Fuel Cladding System Development Trade-Off Study
- The Fission Process and Heat Production
- Categorical Exclusion Determination Form
- There Are Only Three Possible Sources of Energy Which Can Be Used to Generate Electricity in Space – Chemical, Nuclear, Or Solar
- Chapter 13 NUCLEAR FISSION
- Plutonium in Use-From Single Atoms to Multiton Amounts
- Alternative Fuel Sources for Radioisotope
- Nuclear Fuel Resources: Enough to Last?
- The Nuclear Fuel Report: Expanded Summary
- Technological Lessons from the Fukushima Dai-Ichi Accident
- How Should the United States Deal with Nuclear Waste?
- The Future of the Nuclear Fuel Cycle— Overview, Conclusions, and Recommendations 1 Chapter 2
- X-Ray Tomography Study on the Crushing Strength and Irradiation Behaviour of Dedicated Tristructural Isotropic Nuclear Fuel Particles at 1000 °C
- Nuclear Fuel Manufacture at Springfields
- Nuclear Power for Electrical Generation
- R&D and Innovation Needs for Decommissioning of Nuclear
- Quantitative Determination of Crystalline Phases in the Silicide Fuel by the Rietveld Method
- The Fission Properties of Curium Separated from Spent Nuclear Fuel
- Nuclear Power Each Year? If Not, Then 11 Reactors—The Most of Any It’S About Time You Get to Know Nuclear
- Density Determination of Tristructural-Isotropic Nuclear Fuel Using Multiple Projection X-Ray Radiography
- Overview of Tritium Fast-Fission Yields
- Advanced Study of a Tokamak Transmutation System
- Radioactive Effluents from Nuclear Power Stations and Nuclear Fuel Reprocessing Plants in the European Community
- IAEA Nuclear Energy Series Status of Minor Actinide Fuel Development
- Assessment of the Radiotoxicity of Spent Nuclear Fuel from a Fleet of PWR Reactors
- Plutonium Separation in Nuclear Power Programs Status, Problems, and Prospects of Civilian Reprocessing Around the World
- A Comparison of Curium, Neptunium and Americium Transmutation Feasibility Timothée Kooyman, Laurent Buiron, G
- Nuclear Fuel
- Radioisotope Power Systems
- Technical Report 97-13
- Nuclear Energy: the Good, the Bad, and the Debatable
- The Economics of the Nuclear Fuel Cycle
- The Use of Self-Induced XRF to Quantify the Pu Content in PWR Spent Nuclear Fuel
- Nuclear Energy Faqs
- Fusion Energy for Peace and Sustainable Development
- Spent Nuclear Fuel Measurements
- Nuclear Energy: Overview of Congressional Issues
- Nuclear Energy Overview
- Accelerator-Driven Systems (ADS) and Fast Reactors (FR) in Advanced Nuclear Fuel Cycles
- The Front End of the Nuclear Fuel Cycle: Current Issues