This course provides students with an introduction to the key elements of reactor physics. Students completing this course will be able to discuss aspects of reactor physics and the implications that reactor physics has on the engineering of nuclear systems. Students will be able to perform analyses on simple reactor geometries and describe and understand the main reactivity feedback mechanisms, and their significance, on reactor design and control.

Key concepts such as neutron flux and diffusion are first introduced. These are then utilised to demonstrate multiplication and criticality. The neutron life cycle in thermal reactors is described along with fast and delayed neutron production. Reflected reactors and reactor kinetics are discussed including doubling times, reactivity feedback mechanisms, power and temperature coefficients and Xenon poisoning. The course concludes with a discussion on fast reactors and breeding concepts.

The material will be presented by a leading researcher in nuclear reactor physics. The course material is advanced in nature, due to its interdisciplinary content, its delivery in an intensive mode, and the depth of material covered. Students taking this course must have the skills of an Honours level graduate engineer such that they are capable of modelling, analysing and critically reviewing complex engineering systems. A prerequisite for this course is ENGG9741 Introduction to Nuclear Engineering as the material builds on the physical processes at work during fission including neutron flux, criticality, moderation, reactor dynamics and transients.