Gas lasers pumped by runaway electrons preionized diffuse discharge

“…In the experiments, we used a laser pumped by a diffuse discharge, which was thoroughly described in [9]. A highvoltage pulse from a RADAN-220 generator was applied to stainless steel electrodes 30 cm long with a gap d = 1.8 cm between them.…”

“…the external electric circuit. The distribution of the laser photon flux along the optical axis was described by the onedimensional resonator model [9]. It was assumed in calculations that the discharge was spatially homogeneous.…”

“…We have developed excitation technique bused on a double discharge circuit with a pre-pulse formed by a generator with an inductive energy storage device and semiconductor opening switch made on the base of industrial SOS-diodes [6]. It is known that high-power nanosecond excitation pulses can be realized without using an additional source for gap preionization in lasers with electrodes having a small radius of curvature [7][8][9][10]. At a short rise time of the voltage pulse, the breakdown initiated by runaway electrons gives rise to a diffuse plasma, which, at high pressures, serves as an efficient source of spontaneous and stimulated emission at different wavelengths, including the VUV range [9,10].…”

“…It is known that high-power nanosecond excitation pulses can be realized without using an additional source for gap preionization in lasers with electrodes having a small radius of curvature [7][8][9][10]. At a short rise time of the voltage pulse, the breakdown initiated by runaway electrons gives rise to a diffuse plasma, which, at high pressures, serves as an efficient source of spontaneous and stimulated emission at different wavelengths, including the VUV range [9,10].…”

Long pulse UV and VUV gas discharge lasers

“…In the experiments, we used a laser pumped by a diffuse discharge, which was thoroughly described in [9]. A highvoltage pulse from a RADAN-220 generator was applied to stainless steel electrodes 30 cm long with a gap d = 1.8 cm between them.…”

“…the external electric circuit. The distribution of the laser photon flux along the optical axis was described by the onedimensional resonator model [9]. It was assumed in calculations that the discharge was spatially homogeneous.…”

“…We have developed excitation technique bused on a double discharge circuit with a pre-pulse formed by a generator with an inductive energy storage device and semiconductor opening switch made on the base of industrial SOS-diodes [6]. It is known that high-power nanosecond excitation pulses can be realized without using an additional source for gap preionization in lasers with electrodes having a small radius of curvature [7][8][9][10]. At a short rise time of the voltage pulse, the breakdown initiated by runaway electrons gives rise to a diffuse plasma, which, at high pressures, serves as an efficient source of spontaneous and stimulated emission at different wavelengths, including the VUV range [9,10].…”

“…It is known that high-power nanosecond excitation pulses can be realized without using an additional source for gap preionization in lasers with electrodes having a small radius of curvature [7][8][9][10]. At a short rise time of the voltage pulse, the breakdown initiated by runaway electrons gives rise to a diffuse plasma, which, at high pressures, serves as an efficient source of spontaneous and stimulated emission at different wavelengths, including the VUV range [9,10].…”

Long pulse UV and VUV gas discharge lasers

“…When a high-voltage pulse with a short rise time is applied to electrodes providing a sharply non-uniform electric field in a gap, a diffuse discharge is formed in pressured gases due to breakdown initiation by runaway electrons and x-ray radiation. Therewith, the diffuse plasma can effectively emit VUV spontaneously and stimulated radiation [11][12][13].…”

VUV lasing in diffuse discharges formed by runaway electrons

Diffuse Discharges Formed in an Inhomogeneous Electric Field Due to Runaway Electrons