RU2329578C1 - Gas laser with high-frequency excitation - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention is related to the field of quantum electronics and may be used in production of gas lasers that are excited by transverse high-frequency discharge, in production of laser medical equipment and laser technological units. Laser with high-frequency excitation includes source of high-frequency excitation, casing, discharge channel that is formed by potential and grounded high-frequency electrodes, mirrors of optical resonator. Grounded electrode along its whole length is made with dent. Dielectric plate is installed on the dent. Potential electrode is installed on the surface of dielectric plate that is external in respect to dent. Width of potential electrode is less than the width of grounded electrode dent.

EFFECT: increase of laser efficiency with simultaneous simplification of device and technology of its manufacturing.

10 cl, 42 dwg

Description

The invention relates to the field of quantum electronics and can be used in the production of gas lasers excited by a transverse high-frequency (HF) discharge, including waveguide CO ₂ lasers, for laser location and communication systems, as well as in the creation of laser medical equipment and laser technological installations.

It is known that the best energy performance and high resource indices gas (mainly CO ₂₎ laser achieved using HF pump [1]. It is advisable to use relatively low frequencies of RF excitation (up to 40 MHz) for pumping CO ₂ lasers with a transverse RF discharge in tubes with an open resonator. Higher frequencies of RF excitation (~ 100 MHz) are preferable for pumping compact waveguide gas-discharge lasers characterized by the presence of waveguide light resonators in which radiation propagation mainly occurs through the propagation of waveguide modes rather than free-space modes [2]. As waveguides, hollow dielectric guiding structures with a characteristic size of the discharge channel in the case of CO ₂ lasers of 1.5-3 mm, which can have an arbitrary geometric configuration: round, elliptical, square or rectangular, are used.

Known waveguide gas laser with RF excitation [see US Pat. US No. 4169251, IPC H01S 3/097, publ. 09/25/79], containing a waveguide discharge channel formed on two opposite sides by electrodes to which RF power is supplied to excite a gas medium, and on the other two sides by dielectric plates, and resonator mirrors mounted on the ends of the channel.

In this design, the reflecting surfaces of the mirrors have direct contact with the gas discharge plasma, which leads to their rapid degradation and, as a result, to a decrease in the laser resource characteristics. Big problems are associated with the manufacture of an extended cermet structure using adhesive joints or low-temperature soldering of its elements. Both of these processes entail additional pollution and the impossibility of good degassing of the internal volume of the waveguide channel. In addition, different linear expansion coefficients of the parts forming the discharge structure can lead to depressurization of the laser.

A known design of a waveguide gas laser with RF excitation [see US Pat. US No. 4481634, IPC H01S 3/097, publ. 6.11.84], including two parallel, opposite each other longitudinal electrodes, to which the RF power is supplied to excite the gaseous medium. The lower, grounded electrode is made concave in the longitudinal and transverse directions along the entire length, and the narrow upper electrode is respectively convex in the longitudinal and transverse directions.

A big disadvantage of this design is the complexity of the manufacturing technology of an extended curved metal waveguide of the required quality. The cooling of the gas mixture in the discharge channel is mainly in the direction of one grounded electrode, while in the cermet waveguide, the cooling is carried out in the radial direction and is therefore approximately 1.5 times more efficient. Deterioration in the cooling of the discharge channel, as well as waveguide losses and losses due to matching the waveguide with the cavity mirrors, lead to a noticeable decrease in the radiation power and, accordingly, the laser efficiency.

The closest in technical essence to the claimed is a waveguide gas laser with RF excitation [see US Pat. RF № 2244367, IPC H01S 3/097, prior. 05.26.03], which includes an RF pump source, a housing filled with a working gas mixture, a discharge channel inside it, which is bounded on two opposite sides by potential and grounded RF electrodes, and on two other sides by dielectric plates, and highly reflective and installed on the ends of the discharge channel and Beam splitter mirror optical resonator.

In sealed lasers with diffusion cooling of the active medium, the thermal energy released by the gas discharge plasma is removed through the walls of the discharge channel. Therefore, the use of two dielectric plates with relatively low thermal conductivity (for example, the thermal conductivity of ceramic Al ₂ O ₃ widely used in waveguide designs is an order of magnitude lower than the thermal conductivity of an aluminum alloy) does not provide effective cooling of the discharge channel, which is a drawback of this design. In addition, the design of the waveguide channel, as well as that of the analogs, does not allow for the effective matching of the simplest to produce flat resonator mirrors with the waveguide, placing them close to the end of the waveguide. When constructing multichannel lasers with a broken (for example, U-shaped) waveguide resonator, significant waveguide losses are inevitable due to the presence of extended sections due to the design between the waveguide channels. A consequence of these disadvantages is also the low efficiency of the laser.

The technical effect of the proposed gas laser with RF excitation is to increase its efficiency while simplifying the device and its manufacturing technology.

To achieve the above effect, we created a gas laser with high-frequency excitation, including a high-frequency pump source, a housing filled with a working gas mixture, at least one discharge channel formed by a potential and grounded high-frequency electrodes, and mirrors of the optical cavity. New in the device is that the grounded electrode along its entire length is made with at least one recess, while the dielectric plate is placed on the recess, and the potential electrode is located on the surface of the dielectric plate external to the recess, and the potential electrode is smaller the width of the recess of the ground electrode.

The shape and dimensions of the recess in the grounded electrode, which determine the design characteristics of the discharge channel, are set from the conditions for ensuring high stability of the RF discharge at the selected working gas mixture pressure and pump power level. For waveguide gas-discharge lasers, additional requirements to the design parameters of the discharge channel (respectively, to the transverse dimensions of the recess and its length) are determined by the waveguide resonator, which provides effective suppression of higher transverse modes. Approaches to solving these problems are known.

If in the proposed design the grounded electrode is made in the form of a plate with recesses on its two opposite sides, then an additional technical effect is obtained - increasing the output power of the laser emitter due to the formation of several discharge channels and expanding its functionality (see Clause 2 of the Formula). Using an additional lens, it is possible to provide the ability to scan laser radiation by switching the RF excitation signals of individual channels. Approaches to solving this problem are known.

Having performed a grounded electrode in the form of a multifaceted figure with recesses on its flat lateral faces, we obtain a large lasing power due to the formation of several discharge channels with symmetric heating, which ensures minimal distortion of the optical structure (see Section 3 of the Formula).

When performing a grounded electrode in the form of a figure with mutually orthogonal planes with recesses on them, using an external polarizing device to reduce laser beams, it is possible to increase the output power of laser radiation. Approaches to solving this problem are known (see Section 4 of the Formula).

By making a notch in a zigzag shape, and by installing rotary mirrors in the optical cavity, it is possible to increase the output power of the laser without increasing its longitudinal dimensions by lengthening the discharge channel (see Section 5 of the Formula).

Selecting the length of the potential RF electrode less than the length of the grounded electrode will allow you to place the flat mirror of the resonator close to the ends of the waveguide and thereby reduce waveguide losses during the passage of optical radiation in the resonator (see Section 6 of the Formula).

Having performed the discharge channel as a waveguide, we obtain an additional technical effect - high stability of the discharge with respect to ionization-thermal fluctuations at significantly higher than in traditional gas-discharge lasers, working gas pressures and pump power levels (see Section 7 of the Formula).

Having performed channels for convection of the working mixture in the grounded electrode, we will increase the laser efficiency by providing additional convection cooling of the gas in the plasma, as well as its change (see Section 8 of the Formula).

By applying an erosion-protective film to the surface of the recess in the grounded electrode, we will provide a more uniform discharge and protect the surface of the earth electrode from possible plasma erosion during long-term operation (see Clause 9 of the Formula).

If we apply a catalyst film on the surface of the recess in the grounded electrode to regenerate the working mixture, then we will increase the laser emitter life with an increased specific energy consumption (see clause 10 of the Formula).

On figa shows in section a General view of a single-channel gas laser with RF excitation, and on figb - its cross section (example of a specific implementation). The device comprises an RF pump source 1 (RF generator), a housing 2 filled with a working gas mixture, a discharge channel 3 located in the housing, formed by a potential and grounded RF electrodes 4 and 5, respectively, and highly reflective and beam splitting mirrors 6 and 7 installed at the ends of the discharge channel respectively, an optical resonator. In the grounded electrode 5, a recess 8 is made along its entire length, the cross section of the recess 8 in the grounded electrode 5 can be of any shape, for example, a semicircle. A dielectric plate 9 is placed on the recess, on the surface of the outer surface of the recess 8 of which is a potential electrode 4 connected to the RF generator 1 through a vacuum-tight input 10 isolated from the laser housing 2 (see Formula 1).

Figures 2a and 2b (cross section) show a four-channel gas laser including an RF pump source 1, a housing 2 filled with a working gas mixture, four discharge channels 3, and mirrors 6 and 7 of the optical resonators. The discharge channels 3 are formed by recesses 8 located on one side of the grounded electrode 5 and dielectric plates 9 with potential electrodes 4. Vacuum-tight bushings 10 are used to supply RF excitation (see Clause 1 of the Formula).

Figa and 3b (cross section) show a General view of an eight-channel gas laser containing an RF pump source 1, a housing 2 filled with a working gas mixture, discharge channels 3, and optical resonator mirrors 6, 7. The discharge channels 3 are formed by recesses 8 located on two opposite sides of the grounded electrode 5, the supply of RF excitation is carried out through vacuum-tight inputs 10 (see paragraph 2 of the Formula).

Figure 4 shows an eight-channel gas laser with symmetrically arranged discharge channels. The laser contains an RF pump source 1, a housing 2 filled with a working gas mixture, discharge channels formed by recesses 8 on flat faces made in the form of a multifaceted figure of a grounded electrode 5 and flat dielectric plates 9 with potential electrodes connected through vacuum-tight inlets 10 to source 1 HF pumping (see Clause 3 of the Formula).

Fig. 5a shows a section through a two-channel gas laser, and Fig. 5b shows a diagram for converting laser beams therein. In the housing 1 filled with the working gas mixture, there are discharge channels 3 and mirrors 6, 7 of the optical resonators. The discharge channels 3 are formed by recesses 8 located in mutually orthogonal planes of the grounded electrode 5 and dielectric plates 9 with potential electrodes 4. For converging the laser beams into one, a rotary mirror 11 and a selective polarizing mirror 12 are used, transmitting linearly polarized radiation from one laser channel and reflecting orthogonally polarized laser radiation of the second channel. Approaches to solving the problem of reducing laser beams are known (see Section 4 of the Formula).

On figa and 6b (cross section) shows a gas laser with a zigzag discharge channel. The laser contains an RF pump source 1, a housing 2 filled with a working gas mixture, a zigzag discharge channel 3, as well as mirrors 6, 7 of the optical cavity and additional rotary mirrors 13. The discharge structure is formed by recesses 8 in the grounded electrode 5 and dielectric plates 9 with potential electrodes 4 Vacuum-tight bushings 10 serve to supply RF excitation to potential electrodes (see Clause 5 of the Formula).

7 shows a cross section of the discharge structure with additional channels in a grounded electrode for convection of the working mixture. The cross section of the recess 8 in the grounded electrode 5 is made in the form of a triangle, the base of which is a dielectric plate 9 with a potential electrode 4. The channels can be made in the form of a gap 14 in the center of the grounded electrode and additional transverse holes 15 associated with the buffer volume of gas in the laser housing . Approaches to solving this problem are known (see Clause 8 of the Formula).

The device operates as follows (see figure 1). When applying RF voltage from a source of 1 RF pump to the potential and grounded electrodes 4 and 5, respectively, in the discharge channel 3 filled with a working gas mixture, an RF discharge is ignited between the electrodes 4 and 5. The dielectric plate 9 covering the recess 8 in the grounded electrode 5 is a distributed ballast capacitance that stabilizes the discharge, while heat is removed from the gas gap mainly through the walls of the grounded electrode 5. Highly reflective and beam splitting mirrors 6 and 7, respectively, are used to obtain generation. The laser radiation is removed from the resonator through a beam-splitting mirror 7. Since the dielectric plate mounted on the grounded electrode is not a carrier and cannot lead the main metal structure due to thermal differences, the design eliminated the disadvantages associated with the difference in the temperature coefficients of linear expansion of individual parts. This ensures minimal distortion of the optical structure.

Partitioning the potential electrode 4 along its length will make it possible to even out the distribution of the electric field strength along the discharge channel 3, using, for example, a sectioned source of RF pumping 1, and to achieve a more uniform and efficient transfer of power to the discharge channel 3.

The choice of the length of the potential electrode 4 is less than the length of the grounded electrode 5 allows you to place the flat mirrors 6 and 7 of the resonator almost close to the ends of the discharge channel 3 and at the same time exclude the possibility of contact of the surfaces of the mirrors 6 and 7 with the plasma in the discharge channel 3. In the case of a waveguide light resonator, this is additional allows for the most effective matching of plane mirrors 6 and 7 of the resonator with the waveguide (discharge channel 3), placing them close to the end of the waveguide. The potential electrode 4 can be performed by printed circuit mounting on a dielectric plate 9.

The laser emitter can be cooled by pumping refrigerant through channels in the housing 2 or in the grounded electrode 5, as well as by forced air blowing of the housing 2 with a radiator (not shown).

The proposed design will increase the laser efficiency due to more intensive cooling of the discharge channel, made mainly of metal, through which almost the entire heat flux passes, which eliminates the possibility of forming radial temperature gradients, the formation of thermal lenses and lowering the beam quality. Reducing mechanical dielectric parts makes assembly easier. The housing and the grounded electrode can be made by extrusion (for example, from aluminum alloy), which greatly simplifies and reduces the cost of laser manufacturing.

An example of a specific implementation.

To confirm the effectiveness of the claimed device, two mock-up samples of small-sized CO ₂ lasers in a sealed design according to items 1 and 6 of the claims were made at the enterprise. The discharge channel was formed by a recess made by milling in a grounded electrode 150 mm long of aluminum alloy and a dielectric plate 1 mm thick of aluminum oxide ceramic AI-1, on which a potential electrode 135 mm long and 1.5 mm wide was located. Lasers with different shapes of the discharge channel were compared. The cross-section of the recess in the grounded electrode of laser No. 1 was made in the form of an arc with a diameter of 6 mm and a depth of 2.5 mm, and in the grounded electrode of laser No. 2 it was also in the form of a rectangular triangle with a depth of 2.5 mm. The cross-sectional area of the discharge channel of laser No. 1 was ~ 11.2 mm ² , and of laser No. 2 ~ 6.3 mm ² .

Lasers were equipped with flat mirrors. An output mirror with a reflection coefficient of 92% was made on a zinc selenide substrate, and a reflection mirror reflection coefficient on a zirconium bronze substrate of 99.5%. We used a working mixture of CO ₂ : N ₂ : He: Xe = 1: 1: 5: 0.3 at a pressure of 60 mm Hg. The lasers were pumped from an RF generator with an operating frequency of 81.36 MHz. Laser cooling - air.

At a pulse repetition rate of 200 Hz and a pulse duty cycle of ~ 5, the pulsed radiation power of laser No. 1 was 5 W, and the average radiation power was 1 W. For laser No. 2, respectively, a pulsed radiation power of 3 W was obtained with an average power of 0.6 W. Both lasers are characterized by effective suppression of higher transverse modes and stable radiation at the fundamental mode.

The process of energy contribution to the active medium of a laser is accompanied by significant changes in its initial chemical composition. As a result of plasma-chemical reactions in the discharge, activated upon heating of the active medium, the concentration of CO ₂ molecules decreases to a value corresponding to a certain dynamic equilibrium between the processes of dissociation and reduction of CO ₂ molecules in a gas, which leads to a decrease in the inversion of the medium and the generation power. A decrease in the concentration of CO ₂ molecules can reach 50% or more.

The application of a film of a catalytic stabilizer of gas composition to the surface of a recess in a grounded electrode can significantly increase the level of CO ₂ concentration directly in the active medium. With increasing temperature, the effectiveness of the stabilizer of the gas composition increases sharply, therefore, the heating of the stabilizer of the gas composition due to the heat released in the discharge channel, leads to the restoration of a significant part of the degraded CO ₂ molecules. The concentration of CO ₂ molecules also increases somewhat as a result of gas exchange with a buffer volume through channels in a grounded electrode. All these processes lead to an increase in the radiation power and, accordingly, to an increase in the specific energy output.

Thus, the use of the present invention allows the creation of efficient gas lasers with RF excitation, in particular compact sealed CO ₂ lasers, for commercial and special applications. A positive design factor is the possibility of increasing the output power of the laser without increasing its longitudinal dimensions, making the discharge channel zigzag (multi-section).

The proposed solution makes it possible to increase the efficiency of a laser with a waveguide discharge channel by eliminating waveguide losses in the cavity, having flat resonator mirrors and, when the discharge channel is made zigzag, additional rotary mirrors almost close to the ends of the waveguide.

Due to the possibility of arranging multiple laser channels in a single structure, the design allows you to create multi-functional compact multi-channel lasers with independent inclusion of channels.

According to its functional parameters, the proposed device can be widely used, in particular, in laser ranging systems, technology, and medicine. Currently, in accordance with the stated decision, design documentation has been developed for small-scale production of laser devices for low-intensity IR therapy.

Literature

1. Yu.P. Raizer et al. “High-frequency capacitive discharge: Physics. The technique of the experiment. Applications "- M., 1995.

2. Proceedings of the Institute of General Physics of the Academy of Sciences of the USSR "Gas discharge and waveguide molecular lasers", v.17, 1989

Claims (10)

1. A gas laser with high-frequency excitation, including a high-frequency pump source, a housing filled with a working gas mixture, placed in the housing, at least one discharge channel formed by potential and grounded high-frequency electrodes, and mirrors of the optical resonator, characterized in that the grounded electrode at least one recess is made along its entire length, while a dielectric plate is placed on the recess, and the potential electrode is located on top of the recess in relation to the recess dielectric plate, and the width of the potential electrode is less than the width of the recess of the grounded electrode. 2. The laser according to claim 1, characterized in that the grounded electrode is made in the form of a plate with recesses on its two opposite sides. 3. The laser according to claim 1, characterized in that the grounded electrode is made in the form of a multifaceted figure with recesses on its flat side faces. 4. The laser according to claim 1, characterized in that it additionally introduced a polarizing device for converging laser beams, and a grounded electrode is made in the form of a figure with mutually orthogonal planes with recesses on them. 5. The laser according to claim 1, characterized in that the recess is made zigzag, and rotary mirrors are additionally installed in the optical resonator. 6. The laser according to claim 1, characterized in that the length of the potential high-frequency electrode is selected less than the length of the grounded electrode. 7. The laser according to claim 1, characterized in that the discharge channel is made waveguide. 8. The laser according to claim 1, characterized in that the channels for convection of the working mixture are made in the grounded electrode. 9. The laser according to claim 1, characterized in that an erosion-protective film is applied to the surface of the recess in the grounded electrode. 10. The laser according to claim 1, characterized in that a catalyst film for regenerating the working mixture is deposited on the surface of the recess in the grounded electrode.

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