RU192817U1 - Pulsed solid state laser with amplifier - Google Patents

Abstract

The utility model relates to laser technology. A pulsed solid-state laser contains sequentially located along the radiation from a deaf mirror to a partially transparent electro-optical element, a polarizer plate, an optically isotropic active element, a 90-degree radiation polarization plane rotator, a polarizer plate, and rotary mirrors. An optically isotropic active element with a partially polished side surface is installed as an active element. Behind the partially transparent mirror along the radiation there are installed sequentially placed polarizer plate, an optically isotropic active element with a frosted side surface, and a second polarizer plate. Outside the laser propagation axis, two dull mirrors and a quarter-wave plate are installed. The technical result consists in providing the possibility of increasing the energy of monopulses of radiation while maintaining high short-term and long-term stability of the energy of monopulses of radiation. 1 ill.

Description

The utility model relates to laser technology, in particular to solid-state pulsed lasers.

Pulsed solid-state lasers with Q-switching of the resonator, as generators of powerful radiation pulses (monopulses) in the nanosecond range of pulse durations, are widely used in scientific and applied research, in medical devices, in environmental monitoring systems, in technological and metrological installations. As lasers of the IR spectral range, lasers based on crystals containing Nd ³⁺ ions (YIG: Nd, GHGH: Cr, Nd, ISHG: Cr, Nd, etc.) are often used. To modulate the quality factor of the resonator, gates based on electro-optical elements made of DKDP, LiNbO ₃ , RTP, KTP crystals are used.

A known solid-state laser operating in a pulsed-periodic mode, containing a resonator formed by partially transparent and dull mirrors, inside which an active element, a polarizer and an electro-optical element are installed [1]. The spatial structure of multimode radiation of a given laser in the cavity Q-switching modulation mode is heterogeneous, which reduces the laser efficiency and the efficiency of the processes of conversion to other spectral ranges by nonlinear optics methods. Moreover, in metrological installations, increased energy stability of mono-pulses of radiation is required, both short-term (from pulse to pulse) and long-term.

The closest in technical essence to the proposed utility model is a pulsed solid-state laser with a resonator containing sequentially located along the radiation from a deaf mirror to a partially transparent electro-optical element, a polarizer plate, an optically isotropic active element, a 90-degree radiation polarization plane rotator, a plate a polarizer and rotary mirrors providing a second pass of the active element by radiation [2]. In this laser, the active element from AIG: Nd ^{3+ is} made in the form of a cylinder with a polished side surface, which leads to saturation of the laser energy characteristic at high pump pulse energies due to the generation of internal modes in the active element, and, therefore, to an increase in the stability of monopulse energy laser radiation. In this case, the spatial structure of the radiation becomes significantly more uniform.

At the same time, metrological lasers are often required to generate monopulses of radiation with high energy.

The objective of the proposed utility model is to increase the energy of monopulses of laser radiation while maintaining high short-term and long-term stability of the energy of monopulses of radiation.

The problem is solved due to the fact that in a pulsed solid-state laser with a resonator containing sequentially located along the radiation from a deaf mirror to a partially transparent electro-optical element, a polarizer plate, an optically isotropic active element, a 90-degree radiation polarization plane rotator, a polarizer plate and rotary mirrors providing a second pass of the active element by radiation, an optically isotropic active cylindrical element is made with a partially polished side th surface for further partially transparent mirror along the radiation plate-mounted polarizer optically active element with isotropic matt side surface, the second polarizer plate and the axis of the laser radiation is spread two blind quarter-wave plate and mirror installed.

The use of an optically isotropic element with a partially polished side surface in a pulsed laser with a partially ringed resonator makes it possible to increase the generation threshold of internal modes in the volume of the active element and, therefore, increase the energy level of single-pulse radiation in the saturation region of the laser energy characteristic. When passing through the second same optically isotropic active element located outside the resonator, playing the role of an amplifier, the energy increases in accordance with the level of inverse population in the active element, which stabilizes when free generation occurs in an additional resonator formed by two dull mirrors and polarizing plates.

The free generation threshold, which is regulated by the azimuthal orientation of the quarter-wave plate, determines the level of inverse population in the active element of the amplifier and, ultimately, the level of output energy of the proposed laser with an amplifier.

The drawing shows an optical diagram of the device.

The laser resonator is formed by a blind mirror 1 and a partially transparent mirror 2, between which are located the electro-optical element 3, the polarizing plate 4, the optically isotropic cylindrical active element with a partially polished side surface 5, and a 90-degree rotator of the plane of polarization of radiation from optical active quartz 6, a polarizing plate 7, rotary mirrors 8 and 9, providing a second pass of the active element by radiation. Behind the partially transparent mirror 2 along the monopulse radiation there is a polarizer plate 10, an optically isotropic cylindrical active element with a frosted side surface 11, a polarizer plate 12. Deaf mirrors 13, 14 together with a quarter-wave plate 15 and polarizing plates 10 and 12 form a resonator , in which there is free-emission radiation emerging through the polarizing plate 10.

As active elements 5 and 11, elements from optically isotropic garnets AIG: Nd, GHA: Cr, Nd, ISGG: Cr, Nd, etc. can be used. As electro-optical element 3, elements from DKDP, LiNbO ₃ , RTP crystals can be used , KTR.

The proposed laser amplifier operates as follows. In the pulse-periodic mode, during each pump pulse with a “closed” electro-optical shutter, which is formed by a mirror 1, an element 3, and a polarizing plate 4, the inverse population accumulates or the gain increases in the active element 5. When the gain reaches the threshold of internal modes in the peripheral part of the active element, the generation of these modes occurs, the intensity of which continues to increase with increasing energy of the pump pulses, which leads to saturation of the gain in the central part of the active element due to an increase in the intensity of the internal mode radiation scattered in the volume and reflected from the matted sections of the side surface of the active element. As a result, a gain distribution is formed in the active element over the cross section of the active element by the end of the generation of internal modes, which weakly depends on the energy level of the pump pulses.

The smaller the polished side surface area and the larger the matted side surface area, the higher the generation threshold of the internal modes and, therefore, the higher the saturation level of the gain, as well as the level of stabilization of the energy of single pulses of laser radiation. During the synchronous pumping of elements 5 and 11 in the active element 11, the saturation level of the inverse population (or gain) is stabilized when the free generation threshold is exceeded (by increasing the energy of the pumping pulses of the active element 11) in the cavity formed by blind mirrors 13, 14 and polarizing plates 10 , 12. When the azimuthal orientation of the quarter-wave plate 15 changes, the threshold of free generation changes, and, therefore, the saturation level of the gain, as well as the energy level of monopulses zlucheniya exiting the device, which is independent of the pump pulse energy of the active element 11. In this free-radiation exits the cavity through the additional polarizer plate 10.

The increase in the energy of monopulses of radiation in the proposed device occurs at the laser output (due to partial polishing of the side surface of the active element) and at the output of the device (due to the amplifier with a stabilized gain).

Thus, the proposed pulsed solid-state laser with an amplifier makes it possible to increase the energy of mono-pulses of laser radiation while maintaining high short-term and long-term stability of the energy of mono-pulses of radiation.

The source of information:

1. G.M. Zverev, Yu.D. Golyaev. Crystal lasers and their application. M. "Radio and communications", "Rickel", 1994, p. 227.

2. A.A. Bulbin, E.A. Isaeva, A.I. Lyashenko. Pulsed solid state laser. RF patent for utility model No. 141513 dated January 29, 2014.

Claims (1)

A pulsed solid-state laser with a cavity containing sequentially located along the radiation from a deaf mirror to a partially transparent electro-optical element, a polarizing plate, an optically isotropic active element, a 90-degree rotator of the plane of radiation polarization, a polarizing plate and rotary mirrors providing a second pass of the active element radiation, characterized in that an optically isotropic active element with a partially polished side surface is installed as an active element additionally, behind a partially transparent mirror along the radiation linearly polarized in the horizontal plane, there are mounted a sequentially polarized plate, an optically isotropic active element with a frosted side surface, a second polarized plate, and two blind mirrors and a quarter-wavelength mirror are installed outside the laser propagation axis plate.

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