RU2548592C2 - Pulsed two-mode solid-state laser - Google Patents

Abstract

FIELD: physics, optics.

SUBSTANCE: invention relates to laser engineering. A pulsed two-mode solid-stage laser comprises a rotary dihedral rectangular prism for breaking the axis of a resonator, an active element having stimulated Raman scattering (SRS) conversion, a wedge compensator, second dihedral rectangular prism which constitutes, with an output mirror, a single end element of the resonator and a pumping lamp. The laser further includes plane-parallel plates capable of entering/exiting the beam area between the active element and the second dihedral prism at an angle of 90 degrees to each other and a passive laser shutter (PLS₁) between the first rectangular prism and the active element. The input surfaces of the plane-parallel plates and the PLS₁ are coated with a beam-splitting coating having minimal radiation reflection for operating wavelengths and maximum radiation reflection at non-operating wavelengths. The passive laser shutter PLS₁ is inclined relative to the end of the active element at an angle α>d/L, where L is the distance from the active element to the PLS₁, d is the diameter of the active element. The plane-parallel plates and the first PLS₁ can exit from the resonator with simultaneous entry of a second passive laser shutter (PLS₂) into the resonator.

EFFECT: enabling operation of the laser in both a wavelength range safe for the eyes and at basic transition radiation wavelength.

2 cl, 1 dwg

Description

The invention relates to pulsed solid-state lasers operating in the regime of active Q-switching with the possibility of generation at two fixed wavelengths, including in the range safe for the human eye. The invention can be applied in laser rangefinders, emitting in a range safe for the eyes, in laser target designators, for pumping parametric generators.

Of greatest practical interest is the generation of eye-safe radiation in the range λ = 1.53 ... 1.55 μm with the possibility of generation at the main length λn = 1.064 μm. The wavelength of the safe range is obtained as the first Stokes component of the radiation of 1.32-1.35 μm lasers based on crystalline active elements, for example YAG: Nd ³⁺ , KGV: Nd ³⁺ .

Known pulsed solid-state laser with wavelength conversion from stimulated Raman scattering (see 1. Patent for the invention of the Russian Federation No. 21115983, M.cl. H01S 3/30, publ. 07.20.1998), containing in the resonator formed by a dull mirror completely reflecting the radiation with the wavelength of the first Stokes component and transmitting radiation as much as possible with wavelengths corresponding to inactive transitions of the active element and an output mirror completely reflecting the radiation generated at the wavelength of the working transition of the active element a component that partially transmits radiation at the wavelength of the first Stokes component and maximally transmits radiation with wavelengths corresponding to inoperative transitions of the active element and the second Stokes component, the Q factor made on the basis of an electro-optical element and a polarizer or on the basis of a saturated filter with a relaxation time exceeding than by an order of magnitude the round-trip time of the cavity, and the maximum transmission of radiation with a wavelength of the first Stokes component, and crystalline active an element of potassium gadolinium tungstate (KGV), activated by neodymium ions, converting the radiation wavelength λg = 1.351 μm generated at the working transition into Stokes components (SRS conversion), including the first Stokes component λc = 1.54 μm.

However, it is difficult to produce selective resonator mirrors in this laser having a minimum (less than 1%) reflection coefficient for the main radiation wavelength λn = 1.067 μm and maximum (more than 99%) reflection coefficient for wavelengths λ = 1.351 μm and λs = 1.54 microns. In addition, the laser cannot generate at a fundamental wavelength with a higher radiation energy.

Known pulsed solid-state double-frequency laser (see 2. Patent for invention of the Russian Federation No. 2227950, M.cl. H01S 3/107, publ. 04/27/2004), containing in two resonators with a common output mirror an active element with SRS conversion ( in the specific case of the CWG: Nd ³⁺ ), a shutter based on the effect of violation of total internal reflection, along the path of the direct and reflected beam of which there is a polarizer, an electro-optical element, two “blind” ones for the radiation wavelength λс and transparent for radiation with the mirror length λн, the end a resonator element for a wavelength is emitted I λn.

This laser allows you to work with high efficiency both at the main radiation wavelength λn and at a wavelength λc = 1.54 μm safe for the eyes.

However, the design of the laser is complex and its resonators are not sufficiently resistant to misalignment due to climatic and mechanical influences.

The closest in technical essence to the proposed device is a solid-state laser selected as a prototype (see 3. Patent for the invention of the Russian Federation No. 2187868, M.cl. H01S 3/08, publ. 08/20/2002), containing a rotary dihedral rectangular prism for a kink in the cavity axis, an active element, a pump lamp, a wedge compensator, a second dihedral rectangular prism, comprising a single end element of the resonator with a kink in the cavity axis with an output mirror, the edges of the prisms being mutually perpendicular to the dihedral refracting angles polar, and the second edge prism acting as end mirror, perpendicular to the plane passing through the axis of the pump lamp and the active element.

The known device, providing high resistance to temperature and mechanical influences when working at a radiation wavelength λn, does not have the ability to generate a radiation-safe wavelength λs for the eyes.

The technical result of the invention is to expand the functionality of the laser by ensuring its operation both in the eye-safe wavelength range and at the radiation wavelength of the main transition λn in a wide range of temperature and mechanical influences.

The indicated technical result is achieved in that in a laser containing a first dihedral rectangular prism for breaking the axis of the resonator, an active element (AE), a wedge compensator, a second dihedral rectangular prism, which constitutes a single end element of the resonator with the output mirror, and the edges of the prisms at dihedral refracting angles mutually perpendicular, according to the invention, two plane-parallel additionally installed between the AE, which is made with the Raman conversion, and the second two-sided rectangular prism e plates (PP), placed at an angle of 90 ° relative to each other, and a passive laser shutter (PLZ ₁ ), installed between the first two-sided rectangular prism and AE with the possibility of their input / output from the optical axis of the resonator, on the input surfaces of PP and PL31 applied an optical coating that minimally reflects radiation for operating wavelengths and maximally reflects radiation for non-working wavelengths, while PLZ _{1 is} inclined relative to the end of the AE by an angle α> d / L, where L is the distance from AE to PLZ ₁ , d is the diameter of AE, and plane-parallel plates and ne vy passive laser shutter (OWL ₁₎ adapted to the resonator output with simultaneous input of the second resonator in a passive laser resonator (OWL _2).

To ensure the possibility of input / output of PP, PLZ ₁ and PLZ _{2, the} proposed laser is equipped with actuators.

The introduction between the AE, which is performed with SRS conversion, and the second two-sided rectangular prism of two plane-parallel plates installed at an angle of 90 ° relative to each other, with an optical coating deposited on the input faces, minimally (not more than 0.5%) reflecting radiation for workers wavelengths and reflecting (no less than 70%) for the non-working radiation wavelengths, as well as the introduction between the AE and the first rectangular prism dihedral passive Q-switch OWL _1, inclined with respect to the end face AE angle α> d / L applied with the input faces the optical coating is minimal (less than 0.5%) for reflecting light of operating wavelengths and maximum (at least 90%) for reflecting radiation dummy wavelengths, it allows to realize a laser oscillation in a eye-safe radiation wavelength.

The proposed installation location of plane-parallel plates and the first passive laser shutter relative to the active element and the presence on their working faces of an optical coating reflecting radiation at an idle length (in this case for AHE from λH = λ = 1.067 μm) excludes repeated spurious radiation at a λ λ length of AE, thereby allowing the accumulation of the inverse population necessary for the development of generation at an eye-safe wavelength.

The location of two plane-parallel plates at an angle of 90 ° to each other eliminates the displacement of the axial beam relative to the edge of the second dihedral rectangular prism in case of removal of plane-parallel plates from the resonator to ensure operation in the generation mode at a wavelength λn when a second passive laser shutter PLZ _{2 is} introduced. Thus, the position of rib A (see the drawing) always remains in the center of the AE, while ensuring the correct shape of the radiation beam and uniform pumping of the AE.

The drawing shows an optical diagram of the device.

According to the drawing, the proposed pulsed dual-mode solid-state laser consists of a sequentially installed end element, which is an optical gluing of the second dihedral rectangular prism 1 (BR-180 °), which acts as a “blind” mirror and an output mirror 2, two plane-parallel plates 3, installed at an angle of 90 ° to each other, an active element (AE) 4 Raman conversion, pump lamp 5, the wedge compensator 6, the first passive Q-switch (OWL ₁₎ 7 for the wavelength? c = 1.54 mm, the second passive azernogo shutter (OWL ₂₎ 8 for the wavelength λn = 1.067 microns and the first rectangular prism 9 (BR-180 °) to break the resonator axis.

The operation of the device is as follows.

a) The mode of generation of radiation at a wavelength of λs

During the action of the pump pulse, an inverse population is created in the active element 4 with the Raman conversion. Spontaneous radiation emerging from the ends of the active element 4 with SRS conversion (for example, the SHW: Nd ³⁺ ) at the most effective radiation wavelength λн = 1,067 μm, incident on plane-parallel plates 3 and on a passive laser shutter 6, inclined relative to the end of the AE by the angle α> d / L, due to the large reflection coefficient is removed from the resonator and does not fall on the AE. As a result, conditions are created in the resonator for the development of generation at a wavelength λg = 1.351 μm. Upon reaching the radiation density necessary for the enlightenment (opening) of the passive laser shutter 6, monopulse radiation with a wavelength of λg = 1.351 μm appears in the cavity. The frequency shift in the active element 4 with SRS conversion, equal to Δ (λ) ^-1 = 901 cm ^-1 , leads to the appearance in the cavity of the radiation on the first Stokes component λs = 1.54 μm, which is partially transparent for a given radiation wavelength output mirror 2 is output from the laser cavity.

b) The mode of generation of radiation at a wavelength of λn

When issuing a command to switch to the generation mode at the generation wavelength λn, the actuator (for example, a stepper motor, not shown in the drawing) outputs plane-parallel plates 3 and a passive laser shutter PLZ ₁₆ with simultaneous entry into the resonator PLZ ₂ 8. Since it is installed at an angle 90 ° to each other, plane-parallel plates 3 do not displace the rays relative to the optical axis of the resonator, the resonator is not misaligned, and its quality factor does not change due to the input-output of the plates and the PLZ.

When exposed to a pump pulse in the active element 4 with SRS conversion, an inverse population is created. The radiation emerging from the ends of the active element, reflected from the prism 1 (BR-180), passing through the active element 4 and amplifying, begins to brighten the PLZ ₂ 8. The radiation pulse generation energy will increase with an increase in the initial transmission of the passive laser shutter 8 (PLZ ₂ ) . The restriction on the relaxation time of the PLZ provides the generation of a single pulse with a duration in the nanosecond range at a wavelength of λн.

One of the most important features of the proposed laser is that without significant changes in the optical scheme, laser radiation with different wavelengths can be generated on the same active element with high efficiency both at the main radiation wavelength and in the eye-safe wavelength range λc = 1.53 ... 1.55 μm.

In a specific embodiment of a solid-state laser, an active element made of KGW: Nd ^{3+ with a} diameter of 3.5 mm and a length of 50 mm, installed in a leucosapphire tube, was used to ensure the optimal thermal stabilization mode at the maximum permissible operating mode with radiation pulse repetition rates of up to 10 Hz. For a wavelength λc, a YAG: V ³⁺ crystal with an initial transmission T ₀ > 50% was used as a passive laser shutter 6 for a wavelength λс; YAG: Cr ⁴⁺ crystal with an initial transmission T ₀ > 20 was used as a passive laser shutter 8 % The wedge compensator is made in the form of an optical wedge with an angle at the apex of 5 angles. min A stepping motor AM1524-2R-A-0.25-12.5-55 + 16/7 from Fauihaber was used as an actuator.

The reflection coefficient of the output mirror 2 for the radiation wavelength λc = 1.54 μm corresponded to R = 50%, for the radiation wavelength λн = 1.067 μm R = 15% and R = 99.5% for λ = 1.35 μm (transition ⁴ F _3/2 - ⁴ I _13/2 ). The reflection coefficients of the optical coating for a wavelength of λ = 1.067 μm deposited on plane-parallel plates is R> 70%. The reflection coefficients of the optical coating on PLZ ₁ made of YAG: V ³⁺ crystal for a wavelength of λ = 1.067 μm — R≥90%, the absorption coefficient of the optical coating deposited on the ends of the active element and on the working surfaces of the BR-180 prisms corresponded to ρ <0, 5% for wavelengths λg = 1.35 μm and λs = 1.54 μm.

With a pump energy of 6 J using an INP2-35A lamp in the main generation mode, a single pulse energy of 25 mJ was obtained at a wavelength of λn = 1.067 μm, and a generation energy of 10 mJ was obtained at a wavelength λs = 1.54 μm safe for the eyes.

Claims (2)

1. A pulsed bimodal solid-state laser containing a rotary dihedral rectangular prism for breaking the axis of the resonator, an active element (AE), a wedge compensator, a second dihedral rectangular prism, comprising a single end element of the resonator with an output mirror, a pump lamp, characterized in that it is additionally installed with the possibility of input / output from the zone of rays between the AE, which is made with the SRS conversion, and the second two-sided prism, two placed at an angle of 90 degrees. plane-parallel plates (PP) relative to each other and a passive laser shutter (PLZ ₁ ) between the first rectangular prism and AE, a beam-splitting coating is applied to the input surfaces of plane-parallel plates (PP) and PLZ ₁ , minimally reflecting radiation for operating wavelengths and maximally reflecting radiation for broken wavelength, the passive laser shutter OWL ₁ is tilted relative to the end face of AE at an angle α> d / L, where L - distance from AE to OWL _1, d - diameter of the AE, and the plane-parallel plate and the first passive laser sHUTTER p (OWL ₁₎ adapted to the resonator output with simultaneous input of the second resonator in a passive Q-switch (OWL _2). 2. The laser according to claim 1, characterized in that it is equipped with an actuator for input / output of PP, PLZ ₁ and PLZ ₂ .