Study of a plate-electrode XeCl laser with a pulse repetition rate up to 5 kHz

The results of the study of a repetitively pulsed XeCl laser with a high rate of pulse repetition and the electrode assembly based on a multi-section discharge gap with inductance-capacitance stabilisation of the discharge are presented. The multi-section discharge gap is formed by 25 pairs of anode...

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Bibliographic Details
Published in:Quantum electronics (Woodbury, N.Y.) N.Y.), 2012-11, Vol.42 (11), p.980-984
Main Authors: Voevodin, Denis D, Vysotskii, Andrei V, Lazhintsev, Boris V, Pisetskaya, Anastasiya V
Format: Article
Language:English
Subjects:
70 PLASMA PHYSICS AND FUSION TECHNOLOGY
ANODES
CAPACITANCE
CATHODES
EFFICIENCY
ELECTRIC DISCHARGES
ELECTRONS
GAS FLOW
GAS LASERS
HYDROGEN CHLORIDES
INDUCTANCE
KHZ RANGE
LASER RADIATION
MIXTURES
NEON
PLASMA
PULSES
SOUND WAVES
XENON
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Summary:The results of the study of a repetitively pulsed XeCl laser with a high rate of pulse repetition and the electrode assembly based on a multi-section discharge gap with inductance-capacitance stabilisation of the discharge are presented. The multi-section discharge gap is formed by 25 pairs of anode - cathode plates. The discharge formed in the interelectrode gap had the dimensions 250 Multiplication-Sign 12 Multiplication-Sign 2 mm. The studies were performed using the HCl - Xe - Ne laser mixture at the total pressure up to 3.5 atm. The limit value of the radiation pulse repetition rate was equal to 5 kHz. The meansquare deviation of the pulse energy increased from 0.8 % to 1.6 % in the range of repetition rates from 1 to 4.5 kHz and did not exceed 2.4 % at the frequency 5 kHz. The maximal energy of the laser pulse and the efficiency coefficient were equal to 7.9 mJ and 1.6 %, respectively. The maximal power of laser radiation (31 W) was obtained at the repetition rate 5 kHz. A new technique of measuring the gas flow velocity in the interelectrode gap is proposed. The velocity of gas circulation at the maximal pressure of the mixture did not exceed 18 m s{sup -1}. Optical inhomogeneities were observed, caused by a high concentration of electrons in the discharge plasma, by the acoustic wave, arising in the discharge gap, and by the heating of the gas in the discharge. (lasers)
ISSN:1063-7818
1468-4799
DOI:10.1070/QE2012v042n11ABEH014926