RU2664780C1 - Nitrogen laser, excited by longitudinal electric discharge - Google Patents

Abstract

FIELD: optics.

SUBSTANCE: invention relates to laser equipment. nitrogen laser excited by a longitudinal electric discharge comprises a cylindrical partitioned discharge tube with nitrogen, including electrodes for igniting a longitudinal electric discharge, charge and discharge circuits for pulsed discharge supply and a resonator for forming a laser beam. In this case, electrodes of discharge tube are made in form of cylinders with a sharp edge in a discharge tube with inner diameter of 11–17 mm.

EFFECT: technical result is to increase energy and duration of radiation pulse.

1 cl, 2 dwg

Description

The invention relates to quantum electronics and can be used in devices of pulsed gas lasers with a longitudinal electric discharge.

Nitrogen lasers with longitudinal electric discharge are known [1-3]. Lasers contain a cylindrical discharge tube with nitrogen, including rod electrodes, charging and discharge circuits for pulsed discharge power, and a resonator for generating a laser beam.

These lasers use glass or ceramic discharge tubes and consist of one or more sections. Effective laser excitation is achieved with the length of the discharge tubes from 15 to 40 cm, with inner tube diameters of 3-6 mm. Discharge (sharpening) capacitances connected to sections of the discharge tube are pulse charged from the storage capacitance when the switch is triggered. When they are charged, ultraviolet (UV) preionization can be ensured due to additional spark gaps [2]. The formation of a discharge in the tube and the formation of the active medium occurs during the discharge of sharpening tanks on the section of the discharge tube. The nitrogen pressure in the discharge tube is several tens of millimeters of mercury. Laser generation occurs at the front of a current pulse with a rapid decrease in voltage across the electrodes. The discharge current density reaches ~ 0.5-1.5 kA / cm ² . Specific peak pump powers of 0.03-0.15 MW / cm ^{3 are} achieved due to high charging voltages of 30-50 kV. The radiation pulses at a wavelength of ~ 337.1 nm with an energy of 0.03 [2] - 0.2 [1] mJ were obtained. The duration of radiation pulses at half intensity is from 2.5 [2] to 10 [3] ns.

The closest analogue we have taken as a prototype is a nitrogen laser, described in [4], in which a maximum generation energy of 0.3 mJ was obtained. The laser contains a cylindrical glass discharge tube with nitrogen, consisting of 4 sections. The length of the tube in one section is 4.5 cm, the inner diameter of the tube is 4 mm. At the edges of the section are two tantalum rod electrodes located across the tube axis at a distance of 4 mm from each other. The total length of the discharge tube is 26 cm. The total volume of the discharge region is 3.3 cm ³ . At the ends, the discharge tube is closed by quartz windows located at a Brewster angle. To excite a longitudinal discharge, sharpening ceramic capacitors with a capacitance of 0.15 nF per section are used, which are located coaxially with the discharge tube. Their pulse charging occurs when the shock (charging) capacitance of 850 nF is switched. Moreover, charging occurs through the spark gaps formed by the rod electrodes. These sparks provide automatic UV preionization of gas in the discharge gap. As a laser optical resonator, one plane aluminum mirror is used. Under optimal conditions, at a charging voltage of 20 kV, this laser provides a laser pulse with a radiation duration of t _0.5 = 5 ns and an energy of 0.3 mJ.

The disadvantage of the technical solution implemented in the prototype is the limitation (inability to further increase) of the laser radiation energy (E> 0.3 mJ) and the duration of the radiation pulse (t _0.5 > 5 ns) due to an increase in the excitation power (energy). The main reason for this in this design is a violation of the homogeneity of the volume discharge with increasing excitation power, i.e. Instabilities develop in the discharge, which are contracted and the energy of laser radiation decreases.

The objective of the invention is to increase the energy of the radiation pulse and increase its duration.

The specified task in the implementation of the invention is achieved by the fact that in a known laser excited by a longitudinal electric discharge containing a cylindrical sectioned discharge tube with nitrogen, including electrodes for igniting a longitudinal electric discharge, charging and discharge circuits for pulsed discharge power, a resonator for forming a laser beam, according to According to the invention, the electrodes of the discharge tube are made in the form of cylinders with a pointed edge in the discharge tube with an inner diameter of (11-17) mm.

In addition, the specific discharge pump power (P) and the specific pump energy (E) are: P = (1.2-1.5) MW / cm ³ , E = (50-60) mJ / cm ³ .

The mechanism for realizing the ignition of a volume discharge with a higher excitation power and, as a result, obtaining a higher radiation pulse energy and its longer duration, is as follows. The use of discharge electrodes in the form of cylinders with a pointed edge leads to a distortion of the electric field and, therefore, an increase in its intensity on the sharply inhomogeneous internal surface of the electrodes. As a result, a corona discharge arises on the cylindrical cathode and near the tip anodes, which ensures intense gas ionization by the initial electrons. In addition, the proximity of the dielectric surface of the glass tube and the tip electrodes allows you to form a sliding discharge on the surface of the discharge tube, thereby increasing the initial electron concentration along the entire length of the discharge tube. In the cathodic and anodic regions, the rapid germination of the volume stage of the discharge begins, which covers the entire discharge gap and provides effective excitation of the nitrogen laser.

In FIG. 1 shows a laser design and an electrical excitation circuit. The laser has a discharge tube 1, consisting of 2 sections of 200 mm each and an internal diameter of 11.5 mm. Sections are formed by a common cathode 2 and its own anode 3. The cathode 2 and anode 3 are made in the form of cylindrical metal tubes with an inner diameter equal to the inner diameter of the discharge tube 1. The ends of the sections of the discharge tube are mounted coaxially with the anodes at a distance of 2-3 mm from each other. Ceramic capacitors forming the discharge capacitance of the sections C3, are located coaxial discharge tube to eliminate the influence on the distribution of the density of the discharge current over its cross section. The laser optical cavity is formed by a flat or concave aluminum mirror 4 and a quartz window 5, which are mounted on the end attachment points of the sections of the discharge tube.

To pump the laser, a generator is used, made according to the LC-inverter scheme using storage capacitances C1 = 11.2 nF and C2 = 5.6 nF, assembled from TDK UHV-6A, 2700 pF & 30 kV capacitors and two discharge capacitors C3 = 1.9 nF, assembled from KVI-3 capacitors of 20 kV × 470 pF and connected to two tube sections. The generator is connected to the electrical circuit of the laser chamber through a high-voltage coaxial cable with an inductance of L1 ~ 600 nH. The inductance L0 is 100 μH and is used to charge capacitor C2. As a key P, a TPI 10k / 20 brand thyratron is used.

In FIG. Figure 2 shows typical waveforms of current and voltage across capacitance C3, as well as the temporal shape of the radiation pulse. Charging voltage was 24 kV. To effectively use the energy introduced into the active medium, the duration of the excitation pulses was chosen (optimized) by us approximately equal to 40 ns. For these parameters of the discharge tube and pump system, optimal current pulse densities of 2.75 ± 0.25 kA / cm ² , specific power of 1.2-1.5 MW / cm ³ and specific energy of 50-60 mJ / cm ^{3 of the} discharge were realized, which made it possible to obtain the highest generation energy of a nitrogen laser .

At a pressure of technical nitrogen (99.6%), P = 7.5 mm Hg. the total pulse duration of the generated radiation corresponded to the duration of the pump pulse. At a charging voltage U ₀ = 24 kV, the energy in the radiation pulse reached 1.4 ± 0.1 mJ with a duration at half intensity up to 16 ± 2 ns. The maximum peak power of the output beam was 80 kW. Radiation generation developed mainly near the inner wall of the discharge tube in a ring ~ 2.5 mm wide; the laser beam cross-sectional area was 0.6 cm ² . The density of the output radiation recorded from the active medium of the laser was 0.06 mJ / cm ³ . The total laser efficiency (relative to the energy stored in the storage capacitor C1 + C2) was 0.03%. The internal efficiency (relative to the energy stored in the discharge capacity C3) was 0.11%.

When replacing a discharge tube in a nitrogen atmosphere (78% N _2, 21% O ₂₎ with a pressure of 6 mm Hg and at a charging voltage U ₀ = 24 kV, the energy in the radiation pulse was 0.6 mJ at a pulse duration of t _0.5 = 12 ns. Without a system for pumping a gaseous medium in a pulsed-periodic mode of laser operation up to 10 Hz, stable repetition of the discharge and generation characteristics of the laser was maintained.

The scaling of the two-section laser design made it possible to increase the radiation energy to 2 mJ, while the inner diameter of the tube 200 mm long was increased to 17 mm. The generator consisted of capacitances C1 = 17 nF, C2 = 8.4 nF, C3 = 5 nF.

Thus, the proposed device N _{2 of the} laser, excited by a longitudinal discharge, allows to increase the generation energy by more than 5 times compared to the prototype, and the duration of the laser pulse by 3 times. This effect is due to the use of cylindrical tip electrodes and an increase in the diameter of the discharge tube. The use of this invention will allow the creation of efficient N ₂ lasers with a higher energy of the laser beam in a simpler design (without spark preionization), which will expand the scope of its application.

Information sources

1. E.Kh. Bakst, A.N. Panchenko, V.F. Tarasenko. Nitrogen laser pumped by a longitudinal discharge from inductive and capacitive energy storage // Quantum Electronics, V. 25, No. 12, P. 1087-1090, 1998.

2. A.I. Fedorov. Nitrogen laser with longitudinal discharge and UV preionization // Atmospheric and Ocean Optics. 1996. T. 9. No. 2, S. 163-165.

3. A.I. Gorlov, V.V. Kyun, B.C. Skoz, Yu.M. Tokunov. Investigation of a repetitively pulsed nitrogen laser with longitudinal excitation // Quantum Electronics. 1989. V. 16. No. 9. S. 1781-1784.

4. N. Furuhashi, T. Goto. Longitudinal discharge N ₂ laser with automatic preionization using an LC inversion circuit // Rev. Sci. Instrum. 1988. V. 59. N 12. P 2552-2556.

Claims (2)

1. Nitrogen laser excited by a longitudinal electric discharge, comprising a cylindrical sectioned discharge tube with nitrogen, including electrodes for igniting a longitudinal electric discharge, charging and discharge circuits for pulsed power supply of the discharge, a resonator for forming a laser beam, characterized in that the electrodes of the discharge tube are made in the form of cylinders with a pointed edge in a discharge tube with an inner diameter of 11-17 mm. 2. The nitrogen laser according to claim 1, characterized in that the specific discharge pump power (P) and specific pump energy (E) are: P = (1.2-1.5) MW / cm ³ , E = (50-60) mJ / cm ³ .

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