RU993758C - Electronic system of flow-type gas laser - Google Patents

Description

 The invention relates to quantum electronics and can be used to create high-speed gas-discharge lasers with transverse excitation.

 A fast flow electrode system of a gas-discharge laser is known, comprising a cathode sectioned along and across the flow and a common anode in the form of a perforated plate mounted in the gas mixture flow at an angle to the direction of its movement.

 In such an electrode system, the perforated plate clutters the volume of the flow part, causes additional hydraulic resistance and therefore leads to loss of total pressure, which causes additional power consumption of the pumping device.

 The closest in technical essence to the proposed one is the electrode system of a flowing gas laser containing a sectioned cathode and anode in the form of a copper plate. In this system, at elevated pressures of the gas mixture, low values of the specific radiation power occur due to the reduced energy input into a homogeneous glow discharge. The decrease in energy input with increasing pressure occurs due to an increase in the loss of charged particles in elementary processes of recombination and adhesion in the interelectrode gap, while the generation of positive ions at the anode does not increase due to the low current density at the anode.

 The purpose of the invention is to increase the specific energy input into the discharge.

 This is achieved by the fact that in the electrode system of a flowing gas laser containing a cathode and an anode, the surface of the anode facing the cathode is covered with a layer of porous dielectric material.

 In this electrode system, alumina of a thickness of 0.1-20 microns can be used as the dielectric material.

With reduced pressure in the chamber (0.1-0.3) P _slave. produce an electrical breakdown of the oxide film with ignition of a glow discharge, and then set the operating mode.

 The drawing schematically shows the electrode system of a flowing gas discharge laser.

The system comprises a sectioned cathode 1, a ballast block 2, an anode 3 with a dielectric high-temperature porous layer 4. A dielectric layer 4 can be obtained, for example, by oxidizing an aluminum anode to a depth of 0.1-20 μm. At a reduced gas pressure in the discharge chamber (0.1-0.3), a _slave applies a voltage between the sectioned cathode 1 and anode 3 until the electric breakdown of the oxide layer 4 and the gas gap, followed by ignition of the glow discharge. Such a breakdown usually occurs on the microroughnesses of the surface of the anode and has a distributed character. Moreover, the thickness of the dielectric layer 4, less than 0.1 μm, is ineffective, since it is easily destroyed in a glow discharge, with a thickness exceeding 20 μm, high breakdown voltages are required, which complicates the power source and the design of the laser discharge chamber. Resistance provides stability of the discharge in the chamber.

 An increase in the specific energy input into the discharge is achieved by organizing a higher current density at the anode surface, where the electric current passes through the pores of the dielectric high-temperature layer, which form microchannels connecting the anode surface with the interelectrode gas gap. With increasing current density at the anode, the absolute value of the anode potential drop decreases, and the magnitude of the reduced electric field increases. This causes additional gas ionization at the anode and an increase in the concentration of charged particles in the glow discharge plasma.

 Comparative tests of this electrode system showed an increase in the specific energy input in a nitrogen stream of technical purity at a pressure of 130 Torr by about 2 times.

Claims (2)

 1. ELECTRODE SYSTEM OF A FLOW GAS LASER containing a cathode and anode, characterized in that, in order to increase the specific energy input into the discharge, the surface of the anode facing the cathode is covered with a layer of porous dielectric material.  2. The electrode system according to claim 1, characterized in that aluminum oxide with a thickness of 0.1 - 20 microns is used as the dielectric material.

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