RU2300834C2 - Compact continuous solid-state fcd laser (alternatives) - Google Patents

Abstract

FIELD: laser engineering.

SUBSTANCE: proposed laser wherein generation takes place in the course of forced combination dissipation (FCD) has continuous pumping source and cavity holding FCD medium; in addition it is provided with solid-state lasing medium disposed within FCD laser cavity; mirrors of the latter are characterized in ultimately high reflectivity at laser medium generation wavelength and optimal ones at FCD radiation wavelength, as well as ultimately high transmittance at pumping source wavelength. In addition, continuous laser pumping source can be disposed on lateral side of laser medium in which case cavity mirrors used in laser have maximal reflectances at laser medium generation wavelength.

EFFECT: facilitated manufacture.

14 cl, 10 dwg

Description

The invention relates to the field of laser technology, in particular to continuous Raman lasers (lasers, the generation of which is carried out in the process of stimulated Raman scattering - Raman scattering), and can be applied in nonlinear optics, analytical spectroscopy, optical instrumentation, medicine, ecology, optical communication systems, in systems for laser analysis of atmospheric composition, etc.

SRS is a widespread method for converting the frequency of laser radiation into new spectral regions. A variety of combinationally active (or so-called Raman) media in combination with different-frequency pump lasers allows one to obtain radiation, including tunable radiation, in the range from UV to IR. The difficulty, however, lies in the fact that the cross section of two-photon optical processes, which include Raman scattering, is very small (σ _cr ~ ^10-30 cm ^-1 ), and this, in turn, leads to a low Raman gain. Typical Raman amplification factors are 1-3 cm · GW ^-1 for gaseous and liquid Raman active media and 3-50 cm · GW ^-1 for Raman active crystals. As a result, to achieve the SRS excitation threshold, either very high pump intensities or long-range active media are required [1].

Currently, as a rule, compact solid-state Raman lasers are pulsed emitters in which a high power density at a frequency converted in the process of stimulated Raman scattering is achieved by using high-power laser pulses with durations of less than 200 ns [2].

The problem is the creation of continuous compact fully solid-state effective sources of laser radiation that generate in the necessary spectral regions, which would make it possible to use them more widely, for example, in analytical spectroscopy, in particular, in atmospheric composition laser analysis systems to detect pollution.

Continuous generation can be achieved in Raman lasers with a Raman active medium in the form of an optical fiber. In this case, the necessary gain is achieved due to the large (tens of meters) length of interaction of the pump laser radiation with the Raman-active medium and the small (several micrometers) fiber diameter, which makes it possible to increase the pump power density in it.

A device is known that generates continuous Raman radiation in a cavity including a solid-state optical fiber [3]. The device consists of a source of continuous laser pumping, a resonator formed by the output mirror of the pump laser and a highly reflective mirror and including a glass optical fiber, which is a Raman medium, and optical means for removing Raman radiation from the resonator. To effectively introduce pump radiation into an optical fiber, micro lenses (for example, 20 ^x ) coupled to the optical fiber are used. Optical fiber has low losses (less than 50 dB / km) and a length of several tens of meters. The disadvantage of this device is the need to use a low-divergence laser as an pump source for efficiently introducing pump radiation into the fiber and the relatively large size of the device associated with the use of a long Raman active medium.

Closest to the claimed laser in both cases is a continuous Raman laser with a high-Q cavity [4]. The device contains a source of continuous laser pumping and an external (with respect to the laser pumping source) tunable with a piezoelectric element resonator formed by highly reflective mirrors that provide a Fabry-Perot interferometer with a sharpness of more than 50,000. The resonator contains a Raman medium, in particular molecular hydrogen. Obtaining continuous Raman generation in such a device is achieved by accumulating the radiation of the pump field in a high-Q resonator, which is tuned using a piezoelectric element so that the wavelengths of both the pump and Raman radiation are resonant for it. In this case, conditions arise for the efficient conversion of the pump energy into the Raman energy. The disadvantage of this device is the high complexity of its technical implementation, associated with the special technology of applying highly reflective (R≈99.995%) mirror coatings and the need to maintain the optical length of the resonator with submicron accuracy.

The objective of the invention is the creation of a continuous compact technologically simple to manufacture fully solid-state Raman laser.

The problem is solved in two ways as follows.

In the first embodiment, a Raman laser containing a cw laser source and a resonator in which the Raman medium is located further comprises a solid-state laser medium located inside the Raman laser resonator, the resonator mirrors having the highest possible reflection coefficients at the wavelength of the laser medium generation and the optimal SRS radiation at the wavelength, as well as the input mirror, are made with the highest transmittance at the wavelength of the pump source.

The laser medium located inside the resonator has a high absorption coefficient at the wavelength of the radiation from the laser pump source and a high conversion efficiency of the radiation from the laser pump source into laser radiation.

In the second embodiment, a Raman laser containing a cw laser source and a resonator in which the Raman medium is located further comprises a solid-state laser medium located inside the Raman laser cavity, the laser pump source being located on the side of the laser solid-state medium and the cavity mirrors have the highest reflection coefficients at the wavelength of the generation of the laser medium and optimal at the wavelength of the Raman radiation.

The laser medium located inside the resonator has a high absorption coefficient at the wavelength of the radiation from the laser pump source and a high conversion efficiency of the radiation from the laser pump source into laser radiation.

In both cases, a single inventive concept is realized: the energy of the laser pump source is transferred to an additional solid-state laser medium. For maximum energy transfer in the first version of the Raman laser, the cavity mirrors have the highest transmittance at the wavelength of the pump source, and in the second version there are no mirrors between the laser pump source and the laser medium.

The laser pump source is preferably at least one laser diode.

The laser medium located inside the resonator can be selected from Nd ³⁺ : YVO ₄ , Nd ³⁺ : YAG, Nd ³⁺ : KGW, Nd ³⁺ : LSB crystals.

The Raman medium located inside the cavity can be selected from crystals of Ba (NO ₃ ) ₂ , BaWO ₄ , and KGW.

A solid-state laser medium located inside the resonator of a Raman laser can simultaneously be a Raman medium.

The resonator of a Raman laser can be “folded” by introducing an additional spherical mirror into the resonator located at an angle of 5-60 ° to the optical axis of the resonator.

The Raman laser resonator may be annular.

Figure 1 presents the main scheme of the proposed Raman laser in the first embodiment.

Figure 2-7 presents other possible schemes of the proposed Raman laser in the first embodiment.

On Fig presents the main scheme of the proposed Raman laser in the second embodiment.

Figure 9 shows a graph of the dependence of the output power of a continuous Raman laser, implemented according to the first embodiment, on the pump power.

Figure 10 shows the emission spectrum of a continuous Raman laser implemented in the first embodiment.

The scheme of the proposed continuous compact solid-state technologically simple Raman laser in the first embodiment (Fig. 1) includes a laser diode 1 as a source of continuous laser pumping, an optical focusing system 2, and a laser solid-state active medium 3 and a solid-state Raman active medium 4 placed in the cavity formed by the input mirror 5 and the output mirror 6. As a source of continuous laser pumping, a single laser diode 1 can be used, both in this example and EMA laser diodes. The laser diode 1 and the optical system 2 are located on the side of the input mirror 5. The laser active medium 3 is located behind the input mirror 5 and has a high absorption coefficient at the radiation wavelength of the laser pump source 1 and a high efficiency of converting the radiation of the laser pump source into laser radiation. Entrance mirror 5 is flat. The output mirror 6 is spherical. Mirrors 5 and 6 are located relative to each other so that the resonator is hemispherical. The input mirror 5 is made with a maximum transmission at the radiation wavelength of the laser diode 1 and maximum reflection at the wavelength of the generation of the solid-state laser medium 3 and at the radiation wavelength of the SRS medium 4. The ends of the laser active medium 3 and Raman active medium 4 have antireflection coatings for lengths waves generated by the laser medium 3 and the radiation of the SRS medium 4. The output mirror 6 is made with a maximum reflection at the wavelength of the generation of the solid-state laser medium 3 and the optimal reflection at the wavelength of the SRS radiation media 4. Optical system 2 can be replaced or supplemented with optical fiber.

The mirror 5 can be applied directly to the input end face of the laser medium 3 (figure 2).

Mirror 5 can be deposited directly on the input end face of the laser medium 3, and mirror 6 on the output end face of the Raman active medium 4 (Fig. 3). Mirrors 5 and 6 in this case are flat, and the output end of the laser medium 3 and the input end of the SRS medium 4 are “enlightened” by the wavelength of generation of the solid-state laser medium and by the wavelength of the Raman radiation.

Mirror 5 can be deposited directly on the input end face of the laser medium 3, and mirror 6 - on the output spherical end face of the Raman active medium 4 (Fig. 4). The output end face of the laser medium and the input end face of the SRS medium are “enlightened” at the wavelength of generation of the solid-state laser medium and at the wavelength of the Raman radiation.

The laser active medium 3 located in the resonator of the Raman laser can simultaneously be a Raman medium, and the resonator can be made according to one of the schemes of Figs. 1-4 (see, for example, Fig. 5).

The resonator of the Raman laser can be "folded" (Fig.6). In this case, it contains an additional spherical mirror 7, located so that the angle of incidence on it of the radiation generated in the resonator lies in the range of 5-60 °, in particular 45 °. The spherical mirror 7 is highly reflective for radiation with a wavelength of generation of the laser medium and the Raman radiation. Mirrors 6 and 7 are made with radii of curvature such that the spatial radiation mode generated by the laser active medium 3 is constricted in the SRS medium 4. Mirrors 5 and 6 can be made as separate elements or deposited on the input end of the laser medium 3 and output end of Raman active medium 4.

The resonator of the Raman laser can be annular (Fig.7). In this case, the resonator is formed by mirrors 8, 9, 10, located so that the angles of incidence on them of the radiation generated in the resonator lie in the range of 5-70 °, and are highly reflective for radiation with a wavelength of generation of the laser medium. The mirror 8 is made with a maximum transmission for the wavelength of the laser pump source 1. One of the mirrors (preferably 9 or 10) has an optimal transmission at the SRS radiation wavelength, and the other two are highly reflective for this wavelength.

The scheme of the proposed continuous compact solid-state technologically simple Raman laser in the second embodiment (Fig. 8) includes a laser diode 1 as a source of continuous laser pumping, an optical focusing system 2, and a laser solid-state active medium 3 and a solid-state Raman active medium 4, placed into the resonator formed by the mirror 5 and the output mirror 6. The laser diode 1 with the optical focusing system 2 is located on the side of the solid-state laser medium 4. The laser active with 3 is located behind mirror 5 and has a high absorption coefficient at the radiation wavelength of the laser pump source 1 and a high efficiency of converting the radiation of the laser pump source into laser radiation. Mirrors 5 and 6 should form a stable generator. The mirror 5 in this example is flat, and the output mirror 6 is spherical. Mirrors 5 and 6 are located relative to each other so that the resonator is hemispherical. The mirror 5 is made with a maximum reflection at the generation wavelength of the solid-state laser medium 3 and at the radiation wavelength of the SRS medium 4. The ends of the laser active medium 3 and the Raman active medium 4 have antireflection coatings for the wavelengths of the generation of the laser medium 3 and the radiation of the SRS medium 4. The output mirror 6 is made with a maximum reflection at the wavelength of the generation of the solid-state laser medium 3 and optimal reflection at the wavelength of the radiation of the SRS medium 4. Optical system 2 may be absent; in this case, the output window of the laser pump source is in direct contact with the solid-state laser medium.

In both cases, the inventive laser operates as follows. The radiation of the laser diode 1 is focused by the optical system 2 into the laser active medium 3, placed in the resonator of the Raman laser, formed by mirrors 5 and 6, pumping it. The laser medium 3 generates at the frequency of the working transition in a continuous mode. The radiation generated by the laser medium excites the generation in the Raman laser.

The additional introduction of the generating laser medium into the resonator for Raman radiation and the use of mirrors in the resonator with the maximum reflection coefficients at the wavelength of the laser medium generation and optimal for the Raman radiation makes it possible to create a high power density in the Raman laser resonator at the laser medium wavelength sufficient to reach the threshold of stimulated Raman scattering.

The proposed cw Raman laser is compact and technologically simple to implement, because, unlike the prototype [4], precision maintenance of the optical length of the cavity is not required. With a cavity length of a few centimeters, the intermode spectral range, as a rule, is much smaller than the width of the spectrum of the emission of the laser medium and Raman radiation. Therefore, when the generation of the laser medium occurs, self-consistent frequencies of the generation of the laser medium and the Raman medium with resonator modes occur. Generation of radiation by a laser medium can occur at several frequencies, while, in contrast to the prototype, the generation of Raman radiation will also be carried out in a multi-frequency mode.

When the laser active medium is placed inside the Raman laser resonator, the spatial modes of the laser and Raman resonators are also self-consistent, which improves the efficiency of converting the energy of a cw laser source into Raman energy.

The introduction of an additional laser active medium into the Raman laser resonator, the generation of which in the first embodiment of the laser, as a rule, occurs on the spatial mode of the lowest order (TEM ₀₀ ), compared with the prototype, it significantly reduces the requirements for the spectral and spatial characteristics of the radiation from a continuous laser source pump and use as such multimode laser diodes.

A significant reduction in the requirements for reflective coatings of the cavity mirrors (it is not required to achieve very high reflection coefficients R≈99.995) also further simplifies the manufacturing technology of the proposed cw Raman laser in comparison with the prototype.

The following non-limiting example implementation of the present invention.

The proposed laser is implemented according to the scheme shown in FIG. 2, in which an Nd: YVO ₄ crystal with an ion concentration of Nd ³⁺ 1 at.% 2 mm long, cut along the optical axis b, was used as the laser active medium 3. The Nd: YVO ₄ crystal was pumped by the radiation of a laser diode 1 with a wavelength of 0.808 μm. The input and output mirrors of the resonator had reflection coefficients R≈99.95% at wavelengths of 1.064 μm and 1.196 μm. The input mirror was deposited on the input end of the Nd: YVO ₄ crystal and had a maximum transmittance for the radiation of the laser diode at a wavelength of 0.808 μm. The output mirror was spherical with a radius of curvature r = 50 mm. Laser generation of the Nd: YVO ₄ crystal was carried out at a wavelength of 1.064 μm in a continuous mode with simultaneous Raman generation of radiation at a wavelength of 1.196 μm. A 35 mm long barium nitrate crystal (Ba (NO ₃ ) ₂ ) was used as a Raman active medium 4. The output face of the Nd: YVO ₄ crystal and both faces of the Ba (NO ₃ ) ₂ crystal were "clarified" for wavelengths of 1.06 μm and 1.196 μm (residual reflection was not more than 0.1%). The geometric length of the laser cavity was not more than 40 mm. The maximum power of the Raman radiation behind the output mirror of the Raman laser was 2 mW at a laser diode power of ~ 1 W. The spectrum of the output radiation of the Raman laser is shown in Fig.9. The dependence of the output power of the Raman radiation on the power of the laser diode is shown in Fig.10.

Thus, a compact solid-state continuous Raman laser was realized, in the manufacture of elements of which standard technologies were applied.

Information sources

1.T.T. Basiev. Spectroscopy of new Raman-active crystals and solid-state Raman lasers. Advances in Physical Sciences, vol. 169, No. 10, pp. 1449-1155, 1999.

2. W.Koechner. Springer Series in Optical Sciences, v. 1. Solid-State Laser Engineering. Fourth Edition (1996) Ch. 10.3 Raman Laser, pp. 618-626.

3. Hill K.O., Kawasaki B.S., Johnson D.C. Continuous wave Raman oscillator. Canadian Patent No.1115395. Int. Cl. H01S 3/07, 3/08, publ. 12/29/1981.

4. Carlsten J., Repasky K., Brasseur J. Continuous-wave Raman laser having a high-finess cavity. United States Patent No.6151337. Int. Cl. H01S 3/30, publ. 11/21/2000.

Claims (14)

1. A continuous compact solid-state Raman laser containing a cw laser source and a resonator containing a Raman medium formed by mirrors whose reflection coefficients are optimal for generating Raman radiation at a wavelength, characterized in that the Raman laser further comprises a solid-state a laser active medium located inside the resonator having a high absorption coefficient at the wavelength of the radiation of the laser pump source and a high conversion efficiency of the radiation of the laser source laser radiation, the source of continuous laser pumping being the pumping source for the laser medium, and the cavity mirrors have reflection coefficients at the wavelength of the laser medium, which ensures the accumulation of laser power sufficient for the development of SRS generation. 2. A continuous Raman laser according to claim 1, characterized in that the laser pump source is made in the form of at least one laser diode. 3. The continuous Raman laser according to claim 1, characterized in that the laser medium located inside the resonator is made in the form of a crystal Nd ³⁺ : YVO ₄ , or Nd ³⁺ : YAG, or Nd ³⁺ : KGW, or Nd ^{3 +} : LSB. 4. The continuous Raman laser according to claim 1, characterized in that the Raman medium located inside the cavity is made in the form of a Ba (NO ₃ ) ₂ or BaWO ₄ or KGW crystal. 5. The continuous Raman laser according to claim 1, characterized in that the solid-state laser medium is simultaneously a Raman medium. 6. The continuous Raman laser according to claim 1, characterized in that the resonator further comprises a spherical mirror located so that the angle of incidence of the radiation generated in the cavity lies in the range of 5-60 °, highly reflecting on the wavelength of the laser medium and the length SRS radiation waves, the output mirror of the SRS laser and an additional mirror made with radii of curvature such that the spatial radiation mode generated in the cavity by the laser active medium is constricted in the SRS medium. 7. A continuous Raman laser according to claim 1 or 5, characterized in that the resonator is circular. 8. A cw Raman laser containing a cw laser source and a resonator containing a Raman medium formed by mirrors whose reflection coefficients are optimal for generation at a wavelength of Raman radiation, characterized in that the Raman laser further comprises a solid-state active laser a medium inside the resonator having a high absorption coefficient at the wavelength of the radiation of the laser pump source and a high efficiency of converting the radiation of the laser pump source into laser radiation and the source of continuous laser pumping is a pump source for the laser medium and is located on the side of the laser medium, while the cavity mirrors have reflection coefficients at the laser medium generation wavelength, which ensure the accumulation of laser power sufficient for the development of Raman generation. 9. A continuous Raman laser according to claim 8, characterized in that the laser pump source is made in the form of a laser diode. 10. A continuous Raman laser according to claim 8, characterized in that the laser medium located inside the cavity is made in the form of a crystal Nd ³⁺ : YVO ₄ , or Nd ³⁺ : YAG, or Nd ³⁺ : KGW, or Nd ^{3 +} : LSB. 11. A continuous Raman laser according to claim 8, characterized in that the Raman medium located inside the cavity is made in the form of a Ba (NO ₃ ) ₂ , or BaWO ₄ , or KGW crystal. 12. A continuous Raman laser according to claim 8, characterized in that the solid-state laser medium is simultaneously a Raman medium. 13. A continuous Raman laser according to claim 8, characterized in that the resonator further comprises a spherical mirror located so that the angle of incidence of the radiation generated in the cavity lies in the range 5-60 °, highly reflecting on the laser medium wavelength and length SRS radiation waves, the output mirror of the SRS laser and an additional mirror made with radii of curvature such that the spatial radiation mode generated in the cavity by the laser active medium is constricted in the SRS medium. 14. A continuous Raman laser according to claim 8 or 12, characterized in that the resonator is circular.

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