Controlled fusion refers to the process of combining light atomic nuclei to form heavier nuclei, which releases a large amount of energy in the form of heat and light. This process is the same one that powers the sun, and is considered a potentially clean and abundant source of energy on Earth if it can be harnessed. Containment is crucial in this process because the plasma formed during the fusion reaction is extremely high in temperature (in the range of millions of degrees), and it must be kept away from the walls of the containment structure to avoid melting and to prevent energy losses.

The containment of the plasma in the fusion reactor is difficult due to its extreme conditions. At such high temperatures, the plasma consists of charged particles (ions and electrons) which are highly reactive and prone to escaping the containment structure. Moreover, plasma is highly unstable and tends to have irregular turbulence patterns, making it difficult to control and maintain its shape. This necessitates the need for a specially designed containment method to prevent the plasma from touching the walls of the containment structure and to maintain a stable shape for a sufficient amount of time to achieve energy-producing nuclear fusion.

Magnetic fields are considered to be the most promising mode of containment for fusion reactors because they can effectively confine and control charged particles, such as the ions and electrons in plasma. Magnetic fields exert a force on charged particles, causing them to follow the magnetic field lines. By properly designing the magnetic field configuration, the charged particles can be trapped in a closed and controlled path without the need for direct contact with the walls of the containment structure. This prevents the plasma from damaging the walls and allows the reaction to proceed. Some commonly studied magnetic confinement concepts are the tokamak and the stellarator. Both use specially designed magnetic fields to achieve a controlled, stable plasma confinement. In summary, magnetic fields are the most promising mode of containment in controlled fusion research because they can effectively harness and control the plasma in a non-contact fashion, keeping the plasma stable and preventing it from damaging the containment structure.