Abstract
Ion flux formation in a capacitively coupled radio-frequency discharge in argon in axially symmetric chambers of different geometries is studied in experiments and by means of two-dimensional kinetic modeling by the particle-in-cell Monte-Carlo collisions method. A scaling exponent that relates the ratio of voltage drops within sheaths and the ratio of areas of driven and grounded electrodes δS = Arf/A0 is calculated for several types of geometrical discharge asymmetry. It is found that the scaling exponent has a maximum at δS = 2.4. The dc self-bias voltage rises linearly at δS < 2.4 and then becomes saturated. It is demonstrated that a change in δS can substantially increase the ion energy on the electrode practically without disturbing the plasma parameters. The results of self-consistent calculations are in good agreement with experimental data.
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