Electrostatic Discharges during the Joint Impact of Electrons and Electromagnetic Radiation on Glass K-208

Abstract

Electrostatic discharges and radiation-stimulated leakage currents were studied under separate and combined action of 10–40 keV electrons and solar electromagnetic radiation on K-208 glass samples used as cover glass for solar batteries and reflective elements for spacecraft thermal radiators. The values of the electron flux density (φ) were changed in the range of (5 × 10⁸–1 × 10¹¹) cm^–2 s^–1, and the electromagnetic radiation flux corresponded to one equivalent of solar illumination. Irradiation was carried out in a vacuum of 10^–4 Pa. During irradiation, there were two types of discharges: the first type is a discharge from a cone-shaped microprotrusion on the glass surface into the surrounding ionized medium, and the second type of discharge developed along the irradiated surface leaving about 100 nm wide and up to 2 nm deep discharge channels on it. Discharges of both types were accompanied by plasma emissions and generation of electromagnetic pulses. The dependences of the discharge frequency and leakage currents on the parameter φ for electron and combined irradiation were obtained. It was found that for fixed electron energy, discharges of the second type on the samples surface in the case of combined irradiation occur at a lower φ value than that in the case of electron irradiation. It was also found that with combined action the share of breakdowns of cover glass samples on the conductive substrate in the events recorded in the experiments increases significantly. The share of breakdowns of glass samples also increases with increasing energy of the impacting electrons.