Electrostatic Probe Determination of Electron Density in Medium Pressure (0.2–28 Torr) Discharge Plasma of Argon

Abstract

The validity of electron‐density determinations using spherical probe in medium pressure discharge plasmas (r_p/λ_e∼0.3 to 40, where r_p=probe radius, λ_e=electron mean‐free path) are examined for density range N_e=10⁹−10¹¹ cm⁻³. Various collision‐dominated probe theories are used to obtain N_e from both electron and ion saturation currents (I_e and I_i). N_e determined from I_e coincide reasonably with those determined from microwave measurement, while N_e from I_i are always greater than those from microwave measurement by a factor of 2 to 100. The discrepancy increases with increasing gas pressure and total discharge current, and I_i can not be used for N_e determinations. There is ``break'' on the ion current characteristics which is the same as that reported in the measurement of very low‐density flowing afterglow plasmas (N_e8 cm⁻³). Explanation is offered in connection with the unusual increase of ion current caused by the release of electrons from the probe surface by collisions of metastables and the decrease of regular thermal‐motion current because of the short mean‐free path condition (λ₆<r_p).