Magnetic confinement of plasmas is the most highly developed approach to controlled fusion. A large part of the problem of fusion has been the attainment of magnetic field configurations that effectively confine the plasma. A successful configuration must meet three criteria: (1) the plasma must be in a time-independent equilibrium state, (2) the equilibrium must be macroscopically stable, and (3) the leakage of plasma energy to the bounding wall must be small.
Charged particles tend to spiral about a magnetic line of force. It is necessary that these particle trajectories do not intersect the bounding wall. Simultaneously, the thermal energy of all the particles exerts an expansive pressure force on the plasma. For the plasma to be in equilibrium, the magnetic force acting on the electric current within the plasma must balance the pressure force at every point in the plasma.
This equilibrium must be stable, which is to say that the plasma will return to its original state following any small perturbation, such as continual random thermal “noise” fluctuations. In contrast, an unstable plasma would likely depart from its equilibrium state and rapidly (perhaps in less than one-thousandth of a second) escape the confining magnetic field following any small perturbation.
A plasma in stable equilibrium can be maintained indefinitely if the leakage of energy from the plasma is balanced by energy input. If the plasma energy loss is too large, then ignition cannot be achieved. An unavoidable diffusion of energy across the magnetic field lines will occur from the collisions between the particles. The net effect is to transport energy from the hot core to the wall. In theory, this transport process, known as classical diffusion, is not strong in hot fusion plasmas and can be compensated by heat from the alpha particle fusion products. In experiments, however, energy is lost from the plasma at 10 to 100 times that expected from classical diffusion theory. Solution of the anomalous transport problem involves research into fundamental topics in plasma physics, such as plasma turbulence.
Many different types of magnetic configurations for plasma confinement have been devised and tested over the years. These may be grouped into two classes: closed, toroidal configurations and open, linear configurations. Toroidal devices are the most highly developed. In a simple straight magnetic field, the plasma would be free to stream out the ends. End loss can be eliminated by forming the plasma and field in the closed shape of a doughnut, or torus, or, in an approach called mirror confinement, by “plugging” the ends of such a device magnetically and electrostatically.
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