RU203208U1 - Monopulse solid state laser - Google Patents

Abstract

The useful model relates to laser technology, in particular to solid-state pulsed lasers in the mode of electro-optical Q-switching of the cavity, and can be used in nonlinear optics, medicine, and lidar systems for monitoring atmospheric and water pollution. The technical result of the claimed solution, which consists in increasing the output energy of monopulses of laser radiation at a permissible radiation load on the electro-optical element, which ensures a long-term resource of the entire device, is achieved due to the fact that a monopulse solid-state laser with a resonator contains two reflective mirrors, one of which has a rectangular edge, an electro-optical element, a polarizer plate, a quarter-wave and an additional quarter-wave plate, an optically isotropic active element, a prism-roof; the rectangular edge of the blank mirror and the edge of the prism-roof parallel to it lie in the plane of symmetry of the active element. The crystallographic axes of the additional quarter-wave plate are oriented parallel and orthogonal to the edge of the roof-prism. 1 ill.

Description

Monopulse lasers based on crystalline media with Nd ³⁺ ions are widely used in various fields of science and technology. To generate high-power radiation pulses with a duration in the nanosecond range (monopulses), lasers based on yttrium aluminum garnet doped with Nd ³⁺ ions (YAG: Nd ³⁺ ) are most often used in the mode of Q-switching of the cavity with an electro-optical shutter according to the λ / A scheme, where λ is laser wavelength [1].

_{Elements made of DKDP, LiNbO 3} , RTP, KTP, etc. crystals are used as electro-optical elements in the gates.

Among other optical components of the cavity, electro-optical elements have a lower radiation resistance to laser radiation.

Therefore, if it is necessary to increase the output energy of monopulses of laser radiation, various measures are taken to reduce the radiation load on the electro-optical element.

Such measures include: replacing the output mirror of the resonator with an optimal reflection coefficient for a more transparent one, which leads to a decrease in the laser efficiency, or replacing the optical scheme of the resonator from [1] with a scheme with polarization extraction of radiation from the resonator [2]. In the latter scheme, a quarter-wave plate with a corresponding azimuthal orientation makes it possible to form an optimal reflection coefficient of a "polarizing" mirror with an admissible radiation load on the electro-optical element. In this case, the active element must equally amplify radiation with any polarization state, i.e. be optically isotropic.

Mirror-prism resonators are used in the designs of laser emitters, in whose laser heads the active element is conductively cooled through a one-sided heat conductor. The roof prism with a 90 ° apex angle compensates for the effect of the thermal wedge in the cross section of the active element, which allows maintaining the optimal alignment of the cavity, and, consequently, the output energy parameters of the laser.

In such resonators, the formation of a more transparent "polarizing" mirror (a mirror with a lower reflection coefficient), which is required if necessary to increase the output energy of monopulses of radiation and at the same time ensure a long service life of the laser, is hindered by the polarization properties of the roof prism. Nevertheless, the use of a scheme with a polarization output of radiation from a mirror-prism resonator with a quarter-wave plate makes it possible to increase the output energy density of monopulses and the laser efficiency at a low output energy of monopulses of radiation.

The closest in technical essence to the proposed utility model is a monopulse solid-state laser with a resonator [2] containing a reflective mirror, an electro-optical element, a polarizer plate, an optically isotropic active element, a quarter-wave plate, a prism-roof, a reflective mirror with a rectangular edge parallel to the edge at the top of the roof-prism and lying along with this edge in the plane of symmetry of the active element.

However, in this laser, the depolarizing property of the roof prism, associated with the difference in phase jumps for waves with orthogonal polarizations at total internal reflection from the sides of the roof prism [3], does not allow the formation of a more transparent “polarizing” mirror by changing the azimuthal orientation of the quarter-wave plate.

In this case, increasing the pump pulse energy in order to increase the output energy of single pulses of laser radiation will lead to an increase in the radiation load on the electro-optical element and to its destruction.

The objective of this utility model is to increase the output energy of monopulses of solid-state laser radiation while maintaining the permissible radiation load on the electro-optical element, which ensures a long-term service life of the entire device.

The problem is solved due to the fact that in the known monopulse solid-state laser with a cavity containing a reflective mirror, an electro-optical element, a polarizer plate, an optically isotropic active element, a quarter-wave plate, a prism-roof, a reflective mirror with a rectangular edge parallel to the edge at the apex of the prism -the roof and lying along with this edge in the plane of symmetry of the active element, the quarter-wave plate is installed next to the polarizer plate, an additional quarter-wave plate is installed next to the quarter-wave plate, and the crystallographic axes of the additional quarter-wave plate are oriented parallel and orthogonal to the edge of the prism-roof.

Significant differences between the utility model and the prototype laser are: changing the position of the quarter-wave plate in the resonator and additional installation of the second quarter-wave plate, which makes it possible to form a "polarizing" mirror with a low reflection coefficient due to compensation of the depolarizing properties of the prism with an additional quarter-wave plate.

The optical scheme of the proposed device is shown in the drawing. The resonator of a monopulse solid-state laser is formed by a reflective mirror 1 and a reflective mirror with a rectangular edge 2. An electro-optical element 3, a polarizer plate 4, a quarter-wave plate 5, an additional quarter-wave plate 6 are located on the optical axis of the resonator along the direction of the mirror 1, and the crystallographic axes of this plate are oriented parallel and orthogonal to the edge of the roof prism, optically isotropic active element 7, roof prism 8.

Depolarization of radiation in the roof prism occurs due to the difference in phase jumps 8 for waves with orthogonal polarizations with total internal reflection from the sides of the roof prism [3]:

where n is the refractive index of the prism-roof material, θ is the angle of incidence of radiation on the reflecting faces of the prism-roof.

So, for glass with n = 1.55 and θ = 45 °, δ = 90 °. Taking into account the second passage by the radiation of the roof-prism after reflection from the reflective mirror 2, the phase shift is 2δ = 180 °. Taking into account the phase shift after a double pass of the quarter-wave plate 6 by ± 180 °, the additional total phase shift between the orthogonal polarizations of the radiation incident on the quarter-wave plate 5 from the side of plate 6 is 0 ° or 360 ° and is not taken into account.

Monopulse solid-state laser works as follows. At the moment at which, under the influence of the pump radiation pulse, the inverse population (gain) in the active element reaches its maximum value, a high-voltage pulse is applied to the electrodes of the electro-optical element 3, which "opens" the electro-optical shutter formed by the element 3, the mirror 1 and the plate. polarizer 4.

After the "opening" of the electro-optical shutter, a short monopulse of radiation is generated in the resonator, which after the passage of the polarizer plate 4 is linearly polarized in the plane of maximum transmission of the polarizer plate, after the passage of the quarter-wave plate 5 it is elliptically polarized, after a double pass of the quarter-wave plate 6 and the prism-roof 8, the radiation retains the previous state of polarization, and after repeated passage of the quarter-wave plate 5, the state of polarization of the radiation determines the reflection coefficient of the "polarizing" mirror R = cos ² 2θ, where θ is the angle between the crystallographic axes of the plate 5 and the plane of maximum transmission of the polarizer plate.

In this case, the reflection coefficient R can be set low enough to be optimal in terms of the output energy of monopulses of radiation at a higher energy of pump pulses.

Experimental verification has shown the possibility of increasing the output energy of monopulses of radiation of the proposed laser in comparison with the prototype laser by 1.2 times while maintaining the permissible radiation load on the electro-optical element.

Thus, the task set for the utility model of increasing the output energy of monopulses of radiation at an admissible radiation load on the electro-optical element, which ensures a long-term resource of the entire device, can be considered solved.

Sourse of information:

1.G.M. Zverev, Yu.D. Golyaev. Crystal lasers and their applications. M. "Radio and Communication", "Rikel", 1994, p. 227.

2. Garmash V.M., Volodina E.M., Lyashenko A.I., Sapozhnikov S.M., Podkopaev A.V. Features of the development of monopulse YAG: Nd ³⁺ lasers with transverse diode pumping of the active element. Proceedings of the Russian Scientific and Technological Society of Radio Engineering, Electronics and Communications named after A.S. Popov. Series: Acousto-optic and radar methods of measurement and information processing. Issue 12 Moscow, 2019, p. 95-97 - prototype

3.G.S. Landsberg. Optics, "Science", M., 1976, p. 485.

Claims (1)

Monopulse solid-state laser with a resonator containing a reflective mirror, an electro-optical element, a polarizer plate, an optically isotropic active element, a quarter-wave plate, a roof prism, a reflective mirror with a rectangular edge parallel to the edge at the top of the roof prism and lying with this edge in the plane symmetry of the active element, characterized in that the quarter-wave plate is installed next to the polarizer plate, an additional quarter-wave plate is installed next to the quarter-wave plate, and the crystallographic axes of the additional quarter-wave plate are oriented parallel and orthogonal to the edge of the prism-roof.

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