The lectures will be recorded and made available through Moodle/Switchtube.
The exercises associated with each lecture will be provided through Moodle each week; their solutions the week after.
Summary
In this course, one acquires an understanding of the basic neutronics interactions occurring in a nuclear fission reactor as well as the conditions for establishing and controlling a nuclear chain reaction.
Content
- Brief review of nuclear physics
- Nuclear reactions and radioactivity
- Cross sections
- Differences between fusion and fission.
- Nuclear fission
- Characteristics - Nuclear fuel - Introductory elements of neutronics.
- Fissile and fertile materials.
- Element of reactor design
- flux and heat source distribution; properties of different coolants and technological consequences - LWR reactors technology
- overview of the functional scheme of PWR and BWRs; fuel elements; compensation of excess reactivity in PWRs and BWRs (boron, etc,)
- Neutron diffusion and slowing down
- Monoenergetic neutrons - Angular and scalar flux
- Diffusion theory as simplified case of transport theory - Neutron slowing down through elastic scattering. - Multiplying media (reactors)
- Multiplication factors - Criticality condition in simple cases.
- Thermal reactors - Neutron spectra - Multizone reactors - Multigroup theory and general criticality condition - Heterogeneous reactors. - Reactor kinetics
- Point reactor model: prompt and delayed transients - Practical applications. - Reactivity variations and control
- Short, medium and long term reactivity changes. Different means of control. - Advanced reactor designs
- Breeding and transmutation; introduction into Gen-IV reactors
- Professor: Mathieu Hursin
- Professor: Andreas Pautz
- Teacher: Tom Mager
- Teacher: Mackenzie Peter-Fulford Van Rossem