RU100680U1 - LASER WITH OPTICAL PARAMETRIC GENERATOR - Google Patents

Abstract

 A laser with an optical parametric generator, including an optically coupled active element placed in a laser resonator formed by a deaf mirror and an output mirror, an internal mirror mounted between the active element and the output mirror and forming a secondary internal resonator with a nonlinear crystal located in it, an optical device for changing the direction of the axis of the laser resonator mounted between the active element and the internal mirror, characterized in that it is equipped with a back support on which these mirrors and a nonlinear crystal are fixed.

Description

The utility model relates to optical instrumentation, in particular to devices for parametric generation of radiation, and can be used to create sources of directional radiation.

A known laser with an optical parametric generator (LOPG) [1], comprising a laser resonator formed by a blind spherical mirror and a flat output mirror, in which an optically coupled active element is mounted, a flat internal mirror forming a secondary internal resonator with an output mirror, and a polarizer mounted between the flat internal and hollow spherical mirrors, crystal KTP (potassium titanyl phosphate or KTiOPO ₄₎ having plane-parallel working faces and located in the secondary domestic reason torus, wherein the reflectance of the flat output mirror for the radiation output of the optical parametric oscillator is in a range of from 0.1 to 0.8.

Such LOPG with the arrangement of optical elements in one line allows to obtain maximum efficiency, but it also has a maximum length.

A smaller length is LOPG [2], which is the closest in technical essence and the achieved result and selected as a prototype.

LOPG includes an optically coupled active element placed in a laser resonator formed by a deaf mirror and an output mirror, an internal mirror mounted between the active element and the output mirror and forming a secondary internal resonator with the non-linear KTP crystal located in the output mirror, and a polarizer mounted between internal and blind mirrors, an optical device for changing the direction of the axis of the laser resonator, located between the active element and the internal mirror, and to the reflection coefficient of the optical parametric oscillator output mirror for the output radiation (OPG) is in the range of from 0.4 to 0.8.

The presence in the laser resonator of an optical device for changing the direction of the axis of the laser resonator, and the separate arrangement of the deaf, internal and output mirrors, and a nonlinear crystal imposes high requirements on alignment and creates high sensitivity to misalignment of the laser and secondary internal resonators, and, accordingly, reduces the reliability of LOPG during mechanical influences and changes in temperature.

The objective of the utility model is to increase the reliability of LOPG by increasing the resistance of the resonator of the LOPG emitter to mechanical stress and temperature changes.

The essence of the utility model is that a laser with an optical parametric generator, including an optically coupled active element, placed in a laser cavity formed by a deaf mirror and an output mirror, an internal mirror mounted between the active element and the output mirror and forming a secondary internal resonator with the output mirror , with a nonlinear crystal located in it, an optical device for changing the direction of the axis of the laser resonator mounted between the active element and the internal The early mirror, in contrast to the prototype, is equipped with a single support on which these mirrors and a nonlinear crystal are fixed.

The presence of a single support, on which these mirrors and a nonlinear crystal are fixed, allows to increase the reliability of LOPG by increasing the resistance of the resonator of the LOPG emitter to mechanical stress and temperature changes.

The utility model is illustrated in the figure.

The figure shows a diagram of LOPG.

LOPG includes a laser resonator formed by a blind mirror 1 and an output mirror 2, in which optically coupled the active element 3, an internal mirror 4 mounted between the active element 3 and the output mirror 2 and forming a secondary internal resonator with the nonlinear KTP crystal 5, a polarizer 6 mounted between the active element 3 and a blind mirror 1, a shutter 7 for modulating the Q-factor of the laser, mounted between a blind mirror 1 and a polarizer 6, an optical device 8 to change the direction of the axis of the laser resonator mounted between the active element 3 and the inner mirror 4 and made in the form of a prism that changes the direction of the axis of the laser resonator by 180 degrees.

LOPG is equipped with a single support 9, on which these mirrors 1, 2, 4 and a nonlinear crystal 5 are fixed.

Blind mirror 1 has a reflection coefficient ρ> 0.99 for laser radiation in the wavelength region λ ~ 1.06 μm.

The output mirror 2 is made of quartz glass KI or KU and made in the form of a flat mirror, which is deaf for laser radiation with λ ~ 1.06 μm (reflection coefficient ρ> 0, 99) and transmitting the output radiation of LOPG with λ ~ 1.58 μm . It has a reflection coefficient ρ = 0.6 for the output radiation of the LOPG.

The active element 3 (⌀4 × 65 mm) is made of yttrium aluminum garnet with neodymium (YAG) and allows you to get the laser radiation wavelength λ = 1,064 μm.

The inner mirror 4 is made of quartz glass KI or KU, made flat and forms with the output mirror 2 a secondary internal resonator. The inner mirror 4 transmits laser radiation with a wavelength of λ = 1.064 μm and reflects the output radiation of LOPG in the wavelength region of λ ~ 1.58 μm.

In the secondary internal resonator formed by the output mirror 2 and the internal mirror 4, a nonlinear crystal 5 is installed, made of a biaxial KTP crystal, the plane-parallel working faces of which are made perpendicular to the main axis X of the indicatrix of the refractive indices of the KTP crystal with an accuracy of ± 30 '.

The polarizer 6 is made in the form of a thin transparent plate made of K8 glass with plane-parallel working faces and is installed between the active element 3 and the dull mirror 1. In the laser cavity, the polarizer 6 is positioned so that it is normal to plane-parallel working faces with the optical axis of the laser resonator, close to the corner of Brewster.

To increase the degree of polarization of radiation and increase the efficiency of conversion of laser radiation into LOPG radiation, one plane-parallel working face of the polarizer 6 is coated with a B.006 + polarizing interference coating according to OST3-1901-95, which has a radiation length of λ = 1.064 μm when installing polarizer 6 so that the normal to its plane-parallel working faces makes with the optical axis of the laser resonator an angle close to Brewster's angle, the transmittance τ _p> 99% at the location of the electric vector the incidence plane, and transmittance τ _s <1% when arranging the electric vector perpendicular to the plane of incidence.

The KTP 5 crystal is located in the secondary LOPG internal resonator so that the indicated X axis is directed along the optical axis of the resonator, along which polarized laser radiation with a wavelength of λ = 1.064 μm is directed to the KTP 5 crystal, and the main axis Z of the refractive index of the KTP 6 crystal is directed parallel to plane-parallel working faces of the polarizer 6.

In this scheme, the electric vector E of a linearly polarized laser radiation with a wavelength of λ = 1.064 μm is located in the plane of radiation incidence (located in the figure in the drawing plane) on the plane-parallel working faces of the polarizer 6, and, accordingly, is perpendicular to the main axis Z (located in the figure perpendicular to the plane drawing) indicatrix of refractive indices of the KTP 5 crystal.

The electro-optical shutter 7 is designed to modulate the quality factor of the laser.

The optical device 8 for changing the direction of the axis of the laser resonator, installed between the active element 3 and the inner mirror 4, is made in the form of a prism BR-180, changing the direction of the axis of the laser resonator by 180 degrees.

A single support 9, on which mirrors 1, 2, 4 and a nonlinear crystal 5 are fixed, is made of glass.

LOPG works as follows.

In a laser cavity with an active element 3 of YAG, formed by a deaf (for radiation in the wavelength region λ = 1.064 μm) mirror 1 and output mirror 2 (which is simultaneously output for radiation from an organized criminal group with λ ~ 1.58 μm) is generated using shutter 7 is a pulse of polarized radiation with a wavelength of λ = 1.064 μm and a duration of about 10 ns with the location of the electric vector E in the plane of incidence of radiation on the plane-parallel working faces of the polarizer 6. This radiation passes along the optical axis of the LOPG resonator through the internal its mirror 4 to a nonlinear biaxial KTP crystal 5. In a nonlinear KTP 5 crystal located in the secondary internal cavity between the output and internal mirrors 2 and 4, respectively, pulsed polarized radiation with a wavelength of λ = 1.064 μm is parametrically converted to signal wavelength radiation with a length waves in the region of 1.58 microns; and idle wave radiation with a wavelength in the region of 3.3 microns. The radiation of the signal wave is amplified in the resonator composed of the output for radiation of the LOPG and the internal mirrors 2 and 4, respectively, with the KTP 5 crystal located between them, and goes out through the output for the radiation of the LOPG mirror 2.

The presence of an OPG resonator inside the pump laser cavity allows one to obtain high pump power densities in the OPG region, thereby increasing the efficiency of conversion to signal wave radiation. In addition, the multiple reflection of radiation of a signal wave with a wavelength in the region of 1.58 μm in the resonator, composed of the output for the radiation of the organized gas and internal mirrors 2 and 4, respectively, also allows you to increase the efficiency of conversion of radiation with a wavelength of λ = 1,064 μm into radiation with a wavelength in the region of 1.58 microns.

With mechanical influences and temperature changes, the relative position of the BR-180 prism 8, the blind and output mirrors 1 and 2, and the inner mirror 4 and the nonlinear crystal 5 can change. However, since the mentioned mirrors and the nonlinear crystal 5 are mounted on a single support 9, the change in the angular position they are the same, and therefore there is no alignment of the pump laser cavity.

With the electric energy of the LOGG pump pulse equal to 7 J, the energy of the radiation pulse with a wavelength in the region of 1.58 μm is up to 25 mJ.

This ensures an increase in the reliability of LOPG by increasing the resistance of the resonator of the LOPG emitter to mechanical stress and temperature changes.

Information sources.

1 Patent for PM BY No. 3871. Publ. 10/30/07, IPC Н01S 3/00, G02F 1/00.

2 Patent for PM RU №23020. Publ. 05/10/02, IPC H01S 3/00. - The prototype.

Claims (1)

A laser with an optical parametric generator, including an optically coupled active element, placed in a laser resonator formed by a deaf mirror and an output mirror, an internal mirror mounted between the active element and the output mirror and forming a secondary internal resonator with a non-linear crystal located in it, an optical device for changing the direction of the axis of the laser resonator mounted between the active element and the internal mirror, characterized in that it is equipped with a back support on which these mirrors and a nonlinear crystal are fixed.