Lecture

Fusion Reactor Edge Physics

Related lectures (32)

Explores the progress in magnetic confinement fusion, roadmaps to fusion power, ITER components, and the path towards DEMO.

Thermonuclear Fusion: Power Balance

Explores fusion power density, losses, breakeven, ignition, and engineering fusion gain in thermonuclear fusion reactors.

Plasma Physics and Fusion Energy

Introduces Plasma Physics and Fusion Energy, covering energy consumption, fusion reactions, advantages of fusion energy, plasma confinement, challenges in tokamak physics, and the ITER project.

Nuclear Fusion: Creating a Star on Earth

Explores the potential of fusion energy, emphasizing its benefits and challenges, with a focus on the ITER project.

Fusion Energy: Challenges and Solutions

Discusses the importance of energy for development, the need for alternative energy sources, and the potential of fusion energy.

Nuclear Fusion: Creating Stars on Earth

Covers nuclear fusion as a sustainable energy source and its potential to create stars on Earth through advanced research and technology.

Heating, Burning Plasmas, ITER and Route to Fusion Power Plant

Explores heating and burning plasmas, ITER, fusion power plant route, tritium importance, and future prospects.

Heating and Burning Plasmas: ITER and Fusion Power Plant

Explores heating and burning plasmas, ITER, fusion power plants, and the importance of tritium in fusion reactors.

Plasma Physics and Fusion Energy

Explores the complexity of boundary plasma in fusion energy research, focusing on experimental techniques and simulations to understand plasma dynamics and improve fusion reactor design.

Inertial and Magnetic Fusion

Explores the principles of Inertial and Magnetic Fusion, discussing energy balance, challenges, and progress towards burning plasma.

Plasma Physics and Fusion Energy

Explores plasma physics, nuclear fusion, and experimental techniques for studying tokamak boundary plasmas, aiming to achieve clean and sustainable energy production.

Burning Plasmas: Fast Ions Role

Explores burning plasma specifics, fast ions role, losses, MHD modes, turbulence, Alfvén waves interaction, and burn stability.

Tokamak Concept: Main Elements and Properties

Explores the main elements and properties of a tokamak, including shaping, safety factor, equilibrium, and the JET tokamak.

Turbulence in Tokamak Plasmas

Explores the limitations of classical transport models in tokamak plasmas, the impact of turbulence on plasma confinement, and the empirical transport scaling for ITER design.

Approaches to Fusion Energy

Explores the two main approaches to fusion energy, covering conditions for energy generation, compression techniques, physics of Inertial Confinement Fusion, progress in research, and engineering constraints.

Plasma Heating: Neutral Beams

Explores the limitations of ohmic heating in plasma and the advantages and drawbacks of neutral beam injection for additional plasma heating.

Plasma Physics and Fusion Energy

Delves into plasma physics, fusion energy, turbulence, heat flux, and numerical simulations for optimizing fusion reactor operation.

MHD Equilibrium Configurations

Explores MHD equilibrium configurations in 2D, focusing on tokamaks and stellarators for magnetic confinement.

Magnetohydrodynamic Equilibrium Configurations

Covers MHD equilibrium configurations, including tokamak and stellarator concepts, force balance equations, and safety factors.

Fusion Reactions: Kinetic Energy and Impulse

Delves into fusion reactions, energy release, kinetic energy distribution, and impulse in collisions.