EA015572B1 - Apparatus for parametric light oscillation - Google Patents

Abstract

The invention relates to optical instrument making, namely to devices for parametrical light generation and can be used to create infra-red beam radiation sources. The aim of the invention is the development of an apparatus for parametrical light generation, that provides parametrical light generation when pumped with a powerful wide-aperture laser in conditions of strong absorption of a idler wave with high output energy, increased pulse repetition rate, reduced beam divergence and high reliability. Apparatus for parametrical light generation includes ring resonator with a feedback for signal wave, formed by three flat mirrors, and three nonlinear crystals. The first flat mirror serves for input and output of the pumping light and the second mirror, defined by a course of the pumping light in the resonator, serves for the output of the signal wave. Three nonlinear crystals with flat faces and noncritical phase synchronism, having the absorption ratio of the idler wave of ≥ 0.35 cmare mounted between each pair of mirrors on the optical axes of the closed optical circuit created by mirrors. The apparatus has also a telescope mounted in front of the first mirror with an eyepiece turned to said mirror and connecting optically the first mirror with the pumping laser. The scale X of the telescope fulfils the following condition: 5.5 XI≤ I, wherein I- the average radiation power density of the pumping laser; I- a threshold of optical destruction of the nonlinear crystal; and the total length of the nonlinear crystals is selected minimal so that the saturation of the output energy of the signal wave is observed. If the lengths lof the nonlinear crystals according to the course of the pumping light fulfill the following condition: l<l<l, wherein i=1,2,3, the pulse repetition rate and the function reliability of the apparatus are increased with no loss of the output power.

Description

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

A device for parametric generation of light [1], having a ring resonator formed by three flat mirrors, creating a closed optical axial circuit. On the two optical axes of the optical axial circuit, a nonlinear crystal operating in critical phase matching, a first half-wave plate, a Dove prism rotated 45 ° relative to the plane of the resonator, and a second half-wave plate are arranged sequentially along the signal wave in the resonator. In this device, the signal wave field undergoes a rotation of 90 ° with each round-trip of the resonator, which leads to phase correlation over the beam cross section and thereby to a decrease in the divergence of the output radiation of the device.

The known device [1] provides a reduction in the divergence of radiation only when parametric generation of light is performed under conditions of critical phase matching, and thus has an additional limitation on the output energy, since the highest generation efficiency, in particular for nonlinear crystals KT1RO ₄ (KTP), is achieved with uncritical phase synchronism.

The closest in technical essence is a highly efficient parametric converter on nonlinear KTP crystals [2], containing a ring resonator with feedback for the signal wave, formed by three plane mirrors, the first of which serves to input the pump radiation, the second, determined along the pump radiation in the resonator , is the output for the signal wave, and three nonlinear KTP crystals of the same length of 20 mm with flat faces, providing noncritical phase synchronism and are located e between each pair of mirrors on the optical axes of a closed optical circuit created by the mirrors.

The known parametric converter has a limitation, as it is designed to work with lasers generating nanosecond pulses of moderate energy. When pumped by radiation from wide-aperture lasers with increased energy (> 25 mJ), the device does not simultaneously provide high output energy and an increased pulse repetition rate (> 10 Hz). The increase in the pulse repetition rate and the output energy is limited by the strong absorption of the idle wave in nonlinear KTP crystals, especially in the first crystal along the pump radiation, which in combination with the highest radiation intensity in it leads to its failure.

An object of the invention is to provide a device for parametric light generation, which, when pumped by a powerful wide-aperture laser, generates under conditions of strong absorption of an idle wave with high output energy, increased pulse repetition rate, reduced beam divergence and high reliability.

The stated technical problem is solved in that in a device for parametric generation of light, containing a ring resonator with feedback for the signal wave, formed by three flat mirrors, the first of which is used to input and output pump radiation, the second, determined by the direction of the pump radiation in the resonator, is output to the signal wave, and three nonlinear crystal with flat faces and noncritical phase matching with the idler wave absorption coefficient> 0.35 cm ^-1 disposed between each step second mirrors on the optical axis of the optical closed loop created by mirrors introduced telescope mounted in front of the first mirror eyepiece thereto, optically connecting the first mirror to the pump laser, the multiplicity of X satisfies the telescope

5.5 X 1 _N ak ί Ικρ, where I _nak is the average power density of the pump laser radiation;

I _cr is the threshold of optical destruction of a nonlinear crystal, and the total length of nonlinear crystals is chosen to be the minimum at which the output energy of the signal wave is saturated, while the lengths of 1 ₁ nonlinear crystals along the pump radiation, where 1 = 1, 2, 3, satisfy condition 1 ₁ <1 ₂ <1 ₃ . The total length of nonlinear crystals can be determined both experimentally and by calculation.

The choice of the minimum total length of nonlinear crystals leads to a decrease in the absorption of an idle wave, especially in the first crystal. Satisfaction of the condition 11 <12 <13 provides a further decrease in the absorption of the idler wave and a more uniform distribution over the crystals. The manifestation of these effects makes it possible to increase the pulse repetition rate without reducing their energy. The telescope reduces the diameter of the pump beam, which acts as a natural diaphragm, and thereby reduces the effective Fresnel number for the cavity, which helps to reduce the divergence of the output radiation of the device. Calculations and experiments show that the intensity of the signal wave in the ring resonator can be up to 2 times higher than the intensity of the pump radiation, in addition, with multimode radiation, the local pump intensity in the beam cross section can exceed the measured average intensity by about 2.75 times, so the choice of the multiplicity X the telescope, in which the pump radiation intensity is »5.5 times lower than the destruction threshold of the nonlinear crystal, ensures reliable operation of the device.

- 1 015572

The invention is illustrated in the drawing. The figure shows an optical diagram of a device for parametric generation of light. The device contains a ring resonator with feedback for the signal wave, formed by three flat mirrors 1, 2, 3, located along the pump radiation. The first mirror 1 is used for input-output of pump radiation. The second mirror 2 is the output for the signal wave. Mirrors 1, 2, and 3 create a closed optical circuit with optical axes 4, 5, 6. Between each pair of mirrors on the optical axes 4, 5, 6, nonlinear crystals 7, 8, 9 with flat faces are installed, providing noncritical phase synchronism and having a coefficient idle wave absorption> 0.35 cm ^-1 . The pump radiation input / output mirror 1 is optically coupled to the pump laser via a telescope 10 mounted in front of the mirror 1 with an eyepiece thereto. The optical axes 11 and 12 coincide respectively with the directions of input and output of the pump radiation. The optical axis 13 coincides with the direction of output of useful radiation of the signal wave.

The device operates as follows. A beam of polarized radiation from a pulsed pump laser (not shown in the figure), propagating along the optical axis 11, passes through a telescope 10 and reduces its diameter. Then it passes through the input-output mirror 1 of the pump radiation, propagates along the optical axis 4, and creates a region of parametric interaction in the first nonlinear crystal 7, which takes on the role of a natural diaphragm that sets the effective Fresnel number for the resonator. The generated waves (signal and idle), like the pump wave, propagate along the optical axis 4. Having tested on mirror 2 a reflection that is complete for pumping, three waves propagate along the optical axis 5 and continue parametric interaction in the second nonlinear crystal 8. After reflection from mirror 3, which is dull for the signal wave and pump radiation, the radiation of three wavelengths follows along the optical axis 6 and undergoes parametric transformation in the third nonlinear crystal 9. e pump radiation, which is not completely converted in nonlinear crystals 7, 8, and 9, leaves the cavity through mirror 1 in the direction of the optical axis 12. The generated waves, after reflection from mirror 1, which is dull for the signal wave, propagate along the optical axis 4 and they make a complete round trip along the closed optical circuit of the ring resonator. Then they again parametrically interact with the undepleted pump radiation entering the resonator. Regardless of the reflection coefficients of the mirrors at the idle wavelength, absorption of the latter in nonlinear crystals 7, 8, and 9 leads to the fact that the resonator provides feedback for the signal wave. Thus, the device generates a pulse of the signal wave, whose useful radiation outputs Σ ?, · x in the direction of the optical axis 13. For optimal values of 1 ₁ , ι and multiplicity X of the telescope, satisfying the condition 5.5X ² 1 _{[| nk} <1 _cr , device It generates with high reliability pulses with high output energy, an increased repetition rate and a reduced beam divergence.

Nonlinear KTP crystals were used with the dimensions of working plane-parallel faces 4x4 mm ² , with a total length of 45 mm and shear angles θ = 90 °, φ = 0 ° (non-critical phase matching). Flat mirrors made on K8 glass substrates created a closed optical axial contour in the form of a triangle with a perimeter of 80 mm. A lens telescope with a magnification of 1.8 was used. To pump the device, a multimode pulsed garnet laser with neodymium with a wavelength of 1.064 μm, an output energy of up to 100 mJ, a pulse duration of 10 ns, and a beam divergence of 7.5 mrad at the level of 86.5% of the total energy was used. The diameter of the active element of the pump laser was 5 mm. At maximum pump energy, the proposed device generated pulses with an energy of 39 mJ at a pulse repetition rate of 12.5 Hz, which is 5 times higher than in the well-known highly efficient parametric converter [2]. The divergence of the output radiation at a wavelength of 1.57 μm did not exceed 6-6.5 mrad, which amounted to -8 diffraction limits. The proposed device has demonstrated reliable operation (> 10 ⁶ pulses without a significant change in characteristics).

Information Sources Used

1. 8th, Α.ν. 1shade-go1a1shd sauyu YS5SChP5 £ п р го го аш аш с с с | | ί Ш и и и ί ок ок ок ΐ ΐ ΐ ΐ ΐ г г г г (окс (((((((((resonator circuits with image rotation to improve the quality of a beam of nanosecond parametric light generators) / Α.ν. 8ιηί11ι. M.8. In \\ 'cr5 // 1. Θρΐ. 8os. At B. - 2001. - V. 18. R. 706-713.

2. Highly efficient parametric converter on KTP crystals / V.L. Naumov, A.M. Onishchenko, A.S. Podstavkin, A.V. Shestakov // Quantum. electron. - 2000 - T. 30 - S. 632-634 (prototype).

Claims (2)

CLAIM 1. Device for parametric generation of light, containing a ring resonator with feedback for the signal wave, formed by three flat mirrors, the first of which is used for input-output pump radiation, the second, determined by the pump radiation in the resonator, is output for a signal wave, and three nonlinear crystals with flat faces and noncritical phase matching, having an idle wave absorption coefficient of> 0.35 cm ^-1 , located between each pair of mirrors on the optical axes of a closed optical th contour generated mirrors, characterized in that the telescope is introduced, placed in front of the first mirror eyepiece thereto, optically connecting the first mirror to the pump laser, the multiplicity telescope X satisfies the condition wherein _NAC I - average power density of the pump laser radiation; _Icr is the optical destruction threshold of a nonlinear crystal, and the total length of nonlinear crystals is chosen to be the minimum at which the output wave energy of the signal wave is observed. 2. Device for the parametric generation of light according to claim 1, characterized in that the length 1 ₁ non-linear crystals in the course of the pump radiation, where 1 = 1, 2, 3, satisfy the condition 1 ₁ <1 ₂ <1 ₃ .