• calculate spectrum-averaged microscopic cross-sections for thermal neutrons, macroscopic cross-sections for a single isotope and for a mixture of isotopes, reaction probabilities, mean-free-path, mean time for collision, mean energy loss per elastic collision.
• calculate spectrum-averaged microscopic cross-sections for thermal neutrons, access computerized data files of 0.0253eV cross-sections as well as of Maxwellian averaged cross-sections, of fission spectrum averaged cross-sections and of resonance integrals.
• calculate the slowing-down time, the diffusion time, mean distance of displacement while slowing-down, mean distance of displacement while diffusing as a thermal neutron.
• write mathematical formulations (equations) describing neutron balances (gains and losses) in multiplying systems: the equation of continuity, criticality conditions, the point reactor kinetics equations and the rate equations for changes in nuclide densities.
• solve the one-group and two-groups steady state diffusion equation for simplified systems, both non-multiplying and multiplying, as well as for bare and reflected systems; find the spatial neutron and associated power distributions.
• calculate the magnitude of the neutron flux from published information on the nuclear reactor (total power and fuel inventory; specific power; power density and lattice geometry and composition).
• calculate the critical concentration, critical mass and dimensions for bare and reflected cores.
• estimate the magnitude of the four-factors and of the infinite-multiplication-factor in heterogeneous systems.
• calculate the asymptotic reactor period resulting from introduction of positive and negative reactivity and calculate the reactivity that need be introduced in order to change the reactor power level by a given factor in a given time.
• estimate the reactivity effect associated with the buildup of fission products, with the change in fuel temperature and of coolant temperature, and with fuel burnup; calculate the reactivity effect of a given concentration of a thermal neutron absorber uniformly distributed across the core.
• calculate the change in concentration of fission products as a function of the reactor operating time and as a function of the reactor shutdown time.
• solve the rate-equations for the change in the concentration of different isotopes in an operating reactor.

ABET Outcomes:
(a) An ability to apply knowledge of mathematics, science, and engineering
(c) An ability to design a system, component, or process to meet desired needs within realistic constraints such as economic, environmental, social, political, ethical, health and safety, manufacturability, and sustainability
(k) An ability to use the techniques, skills, and modern engineering tools necessary for engineering practice.