General principles of magnetic fusion confinement
General principles of magnetic fusion confinement
A few of the areas are described in which there is close interaction between atomic/molecular (A and M) and magnetic fusion physics. The comparisons between predictions of neoclassical transport theory and experiment depend on knowledge of ionization and recombination rate coefficients. Modeling of divertor/scrapeoff plasmas requires better low energy charge exchange cross sections for H + A/sup n+/ collisions. The range of validity of neutral beam trapping cross sections must be broadened, both to encompass the energies typical of present injection experiments and to deal with the problem of prompt trapping of highly excited beam atoms at high energy. Plasma fueling models present certain anomalies that could be resolved by calculation and measurement of low energy (<1 keV) charge exchange cross sections.
- University of North Texas United States
Ionization, Beam Injection, Tokamak Devices, Instability, Neoclassical Transport Theory, Recombination, Thermonuclear Devices, Transport Theory 700105* -- Fusion Energy-- Plasma Research-- Plasma Kinetics-Theoretical-- (-1987), Neutral Atom Beam Injection, Plasma Instability, 70 Plasma Physics And Fusion Technology, Plasma Drift, Plasma Macroinstabilities, Impurities, Closed Plasma Devices
Ionization, Beam Injection, Tokamak Devices, Instability, Neoclassical Transport Theory, Recombination, Thermonuclear Devices, Transport Theory 700105* -- Fusion Energy-- Plasma Research-- Plasma Kinetics-Theoretical-- (-1987), Neutral Atom Beam Injection, Plasma Instability, 70 Plasma Physics And Fusion Technology, Plasma Drift, Plasma Macroinstabilities, Impurities, Closed Plasma Devices
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