Ion acceleration in plasmas emerging from a helicon-heated magnetic-mirror device.

Using laser-induced fluorescence, measurements have been made of metastable argon-ion, Ar[SUP+]*(3d[SUP4]F[SUB&frac72;], velocity distributions on the major axis of an axisymmetric magnetic-mirror device whose plasma is sustained by helicon wave absorption. Within the mirror, these ions have sub-eV temperature and, at most, a subthermal axial drift. In the region outside the mirror coils, conditions are found where these ions have a field-parallel velocity above the acoustic speed, to an axial energy of ∼30 eV, while the field-parallel ion temperature remains low. The supersonic Ar[SUP+]*(3d[SUP4]F[SUB&frac72;] are accelerated to one-third of their final energy within a short region in the plasma column, ⩽1 cm, and continue to accelerate over the next 5 cm. Neutral-gas density strongly affects the supersonic Ar[SUP+]*(3d[SUP4]F[SUB&frac72;] density. [ABSTRACT FROM AUTHOR]