Lectures related to Exercise Sessions: Important Concepts and Nuclear Reactor Activity

Introduction to Nuclear Engineering: Chain Reactions and Fuel Cycles

Explores chain reactions, criticality, reactor types, and fuel cycles in nuclear engineering.

Covers the formalism and criticality analysis of nuclear reactors, focusing on mathematical equations and reactor stability.

Reactor Technology: Reactivity Variations and Control

Explores reactivity variations in reactor technology, covering short-term, medium-term, and long-term effects, means of control, and consequences.

Introduction to Nuclear Engineering

Introduces nuclear engineering, covering reactions, chain reactions, fuel cycle, criticality, and multiplication factors.

The Diffusion of Neutrons

Covers the transport of neutrons, scalar neutron flux, neutron currents, and more, along with fuel cycles and types of nuclear reactors.

Neutron Transport Theory: Fundamentals and Applications

Explores neutron transport theory, scalar neutron flux, and Fick's law in reactor physics.

Neutron chain-reacting systems

Explores chain reactions, multiplication factor, fuel cycles, reactor design, and types of nuclear reactors, ending with a summary of key concepts.

Physics of Nuclear Reactors: Fundamentals and Advanced Concepts

Explores the fundamentals and challenges of nuclear reactors, covering neutron diffusion, fission, breeding, transmutation, and advanced technologies.

Neutron Physics: Reactor Behavior

Covers neutron physics in nuclear reactors, including criticality, fission, and neutron distribution.

Introduction to Nuclear Engineering

Introduces nuclear engineering concepts, covering reactor technology, physics, safety measures, fission reactions, and reactor safety.

Multiplying media: Analytical Solutions and Non-leakage Probability

Covers media containing fuel, analytical solutions, and non-leakage probability for thermal and fast neutrons.

Introduction and Review of Nuclear Physics

Covers the basics of nuclear physics, including reactor physics, neutron interactions, fission, fusion, and radioactivity.

Reactor Kinetics: Point Kinetics Equations

Covers reactor kinetics, point kinetics equations, numerical solutions, and heterogeneous lattice effects.

Neutron Kinetics: Reactor Kinetics and Point Kinetics Equations

Explores reactor kinetics, reactivity equations, and point kinetics for neutron population dynamics in nuclear reactors.

Reactor Technology: Reactivity Variations and Control

Explores reactivity variations, control mechanisms, and the impact of the Doppler effect on reactor temperature.

Introduction to Nuclear Engineering

Introduces nuclear engineering, covering reactor types, components, and thermodynamics, including pressurized water reactors and boiling water reactors.

Nuclear Reactor Accidents: TMI2 and Chernobyl

Explores the TMI2 and Chernobyl nuclear reactor accidents, safety features, and Generation IV reactors.

Neutron Physics: Reactor Overview

Covers neutron interactions, fission products, energy release, and reactor design considerations.

Nuclear Reactor Physics: Reactor Core Analysis

Covers the analysis of reactor cores in nuclear physics and their impact on performance and safety.

Nuclear Reactors: Concepts and Analysis

Explores nuclear reactor physics, covering basic principles, specific reactor types, accidents like Chernobyl, and advanced technologies.