RU2497249C1 - Solid-state upconversion laser - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: solid-state upconversion laser includes an upconversion laser medium placed in an optical resonator, and a pumping device which includes two semiconductor radiation sources at wavelengths λ1 and λ2 and a fibre module arranged such that optical outputs of both pumping radiation sources are interfaced with the fibre module, and the focusing system is achromatic at wavelengths λ1 and λ2 and is arranged such that the output of the fibre module is interfaced through it with the upconversion laser medium.

EFFECT: homogenisation and high spatial concentration of pumping radiation.

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Description

The invention relates to laser technology and can be used to create short-wavelength sources of coherent radiation.

A solid-state up-conversion laser is known (US patent No. 5008890, publ. 04.16.1991, H01S 3/16), including an up-conversion laser medium in the form of an Er: YLF crystal placed in an optical resonator, and a pump device including a semiconductor laser source generating radiation at a wavelength of 797 nm.

A solid-state up-conversion laser is known (RM Macfarlane, F. Tong, AJ Silversmith and W. Lenth "Violet cw neodymium upconversion laser" Appl. Phys. Lett. V.52, p.1300, 1988), including an up-conversion laser medium in the form of an Nd: LaF ₃ crystal placed in an optical resonator and a pump device including two laser sources based on cw dye lasers generating radiation at wavelengths λ1 = 788 nm and λ2 = 591 nm.

A solid-state up-conversion laser is known (US patent No. 5805631, publ. 08.08.1998, H01S 3/14), including an up-conversion laser medium in the form of an optical waveguide activated by Pr and Yb ions and placed in an optical resonator, as well as a pump device comprising a semiconductor laser source generating radiation in the wavelength range from λ1 = 780 nm to λ2 = 900 nm, and a focusing system for introducing pump radiation into the optical waveguide.

The closest in technical essence to the claimed invention and adopted as a prototype is an up-conversion laser (US patent No. 4949348, publ. 08/14/1990, H01S 3/16), including an up-conversion laser medium placed in an optical resonator in the form of a Tm crystal: YLF and a pumping device, which includes two laser sources based on semiconductor lasers generating radiation at wavelengths λ1 = 781 nm and λ2 = 649 nm, and a focusing system for introducing pump radiation into an up-conversion laser medium.

The main disadvantage of the prototype is the low efficiency of the up-conversion of pump radiation.

The objective of the invention is to increase the efficiency of up-conversion of pump radiation.

The technical result consists in homogenization and a high spatial concentration of the pump radiation beam when two semiconductor lasers with different wavelengths are used in the pump device.

The efficiency of up-conversion of pump radiation is directly related to the degree of homogenization of the radiation beams interacting with the up-conversion laser medium. The higher the degree of their spatio-temporal overlap, the higher the laser efficiency. In the inventive solid-state up-conversion laser, the indicated technical result is achieved by combining the pump beams of two semiconductor lasers in a fiber-optic adder and their subsequent focusing into the up-conversion medium using an achromatic focusing system.

The essence of the invention lies in the fact that in a solid-state up-conversion laser, including an up-conversion laser medium placed in an optical resonator, and a pump device, including two semiconductor radiation sources at wavelengths λ1 and λ2 and a focusing system, the pump device further includes a fiber a module arranged in such a way that the optical outputs of both pump radiation sources are coupled to the fiber module, and the focusing system is achromatic at wavelengths λ1 and λ2 and located wife in such a way that the output of the fiber module is interfaced through it with the up-conversion laser medium.

In addition, the fiber module in the inventive laser can be made in the form of a Y-shaped fiber adder.

In addition, the fiber module in the inventive laser can be made in the form of a sequentially arranged spectrally selective system for introducing radiation into the fiber and a composite optical fiber including a core, an inner and an outer shell. In this case, the ratio of the refractive indices of the materials of the core and the inner shell of the composite optical fiber should be no less than the numerical aperture of the fiber for radiation with a smaller wavelength λ1 and λ2, and the ratio of the refractive indices of the materials of the inner shell and the outer shell of the composite optical fiber is not smaller values of the numerical aperture of the fiber for radiation with a larger wavelength λ1 and λ2.

In addition, the ratio of the diameters of the shells of the composite optical fiber can be chosen equal to the ratio of the wavelengths of the pump radiation.

The up-conversion mechanism in optical-pumped solid-state lasers requires a two-stage process for exciting a laser medium, including absorption of pump radiation from the ground state with population of an intermediate excited state and absorption of pump radiation from an intermediate excited state with population of a final excited state, the relaxation of which is accompanied by the emission of short-wavelength photons . The choice of solid-state up-conversion media that allow the use of monochromatic pump radiation is extremely limited, and the efficiency of up-conversion in such media is noticeably lower than in media requiring bichromatic excitation. Glasses and crystals activated by rare-earth ions are known in which optical transitions between the electronic states of a quantum system are capable of efficiently populating high-lying energy levels as a result of two-stage absorption of two-frequency optical radiation. Obviously, the choice of pump radiation frequencies is determined by the transition energies between the quantum states of the laser medium. The easiest way to build an up-conversion laser pump system is to use two frequency-tunable lasers (for example, dye lasers). In this case, the exact selection of the necessary pump frequencies does not present a problem, as, incidentally, the spatial reduction of pump beams in the active medium does. However, dye lasers are difficult to use as pump sources for industrial applications of up-conversion lasers due to the complexity of their design and control, as well as due to high operating costs.

The most promising option for constructing a two-frequency optical pump system for a solid-state up-conversion laser is the use of two semiconductor lasers. Exact adjustment of the radiation frequencies of these sources can be ensured by changing the temperature of the laser transitions. Nevertheless, the success of the practical implementation of this scheme is inextricably linked with overcoming the problem of spatial mismatch of the pump beams of two semiconductor lasers generating radiation at two significantly different frequencies.

Spatial matching of pump radiation beams in the claimed invention is proposed to be ensured due to the combined use of a fiber module in the pump device for spatial mixing of pump radiation beams at different wavelengths and an achromatic system for focusing radiation into an up-conversion medium (in this case, by achromatic focusing system we mean such a system whose focal lengths at the selected wavelengths λ1 and λ2 differ by no more than 5%).

The invention is illustrated by drawings, which show the optical circuit of the inventive laser. Figure 1 shows the optical diagram of a solid-state up-conversion laser with a pump device that includes a fiber module in the form of a Y-shaped fiber adder. Figure 2 shows the optical diagram of a pumping device with a fiber module in the form of a spectrally selective system for introducing radiation into the fiber and a composite optical fiber including a core, an inner and outer shell. Figure 3 shows an optical scheme for outputting pump radiation from a composite optical fiber with an illustration of the delivery of pump radiation beams of various wavelengths to an up-conversion medium.

Figure 1 shows a solid-state up-conversion medium 1 located inside an optical resonator formed by mirrors 2 and 3, a semiconductor pump radiation source 4, generating radiation at a wavelength of λ1, a semiconductor pump radiation source 5, generating radiation at a wavelength of λ2, fiber module 6 in the form of a Y-shaped fiber adder with optical inputs 7 and 8 and optical output 9 and an achromatic focusing system 10. FIG. 2 shows a fiber module 6 including a spectrally selective system 1 1, introducing radiation into a fiber, consisting, for example, of a dichroic mirror 12 and a lens 13, as well as a composite optical fiber 14. FIG. 3 also shows a composite optical fiber 14 with a core 15, an inner shell 16 and an outer shell 17. In addition, figure 3 illustrates the progress of the pump beams through the achromatic focusing system 10 under the assumption that λ1> λ2.

The inventive device operates as follows. The radiation of the semiconductor laser pump sources 4 and 5 is simultaneously directed to the fiber module 6, in which the pump beams are homogenized. In the case of using a fiber module 6, which includes a spectrally selective system 11 for introducing pump radiation into the composite optical fiber 14 of the lens 13, the short-wave component of the pump radiation is focused by the indicated lens 13 into the region of the core 15, and the long-wave component into the region of the inner shell 16 of the composite optical fiber 14. The conditions of total internal reflection keep the spectral components of the pump radiation in the mode of waveguide propagation. At the output of the composite optical fiber 14, two beams with the same diffraction divergence are formed. This equality is ensured by the choice of the ratio of the diameters of the inner 16 and outer 17 shells of the composite optical fiber 14, equal to the ratio of the wavelengths of the pump radiation. The precision spatial reduction of the pump beams and their maximum concentration in the up-conversion medium 1 is ensured by the achromatic focusing system 10. As a result of the absorption of two-frequency pump radiation in the up-conversion medium 1, high-lying energy levels are excited with subsequent radiative relaxation. Spontaneous emission is amplified in the up-conversion medium 1, and as a result of multiple passage through it due to reflection from the mirrors of the resonator 2, 3, a beam of coherent short-wave radiation is formed in the solid-state up-conversion laser.

Among the known technical solutions, the inventor did not find solid-state up-conversion lasers containing a pump device with a fiber module for homogenizing pump beams and an achromatic focusing system for their simultaneous spatial alignment and concentration, which indicates that the invention meets the novelty criterion. The performance of the claimed device is verified experimentally. It is shown that the efficiency of a solid-state up-conversion laser containing the pump device described in the invention can be increased by a factor of 1.2. In the framework of this approach, the sufficiency of essential features to achieve the technical goal solved by the claimed device is substantiated.

When assessing the significance of the invention for industrial applications, it should be noted that the inventive device provides the possibility of generating short-wave radiation using two long-wave pump sources with high efficiency of up-conversion of radiation, achieved due to the high spatial concentration of the pump radiation. Such solid-state up-conversion lasers can be used as radiation sources in laser projection systems and information recording systems.

Claims (4)

1. A solid state up-conversion laser, including an up-conversion laser medium placed in an optical resonator, and a pump device, including two semiconductor radiation sources at wavelengths λ1 and λ2 and a focusing system, characterized in that the pump device further includes a fiber module, located so that the optical outputs of both sources of pump radiation are coupled to the fiber module, and the focusing system is achromatic at wavelengths λ1 and λ2 and is located in such a way that the output of the fiber module is interfaced through it with an up-conversion laser medium. 2. Solid state up-conversion laser according to claim 1, characterized in that the fiber module is made in the form of a Y-shaped fiber adder. 3. The solid-state up-conversion laser according to claim 1, characterized in that the fiber module is made in the form of a sequentially arranged spectrally selective system for introducing radiation into the fiber and a composite optical fiber including a core, an inner and an outer shell, the ratio of refractive indices of the core materials and the inner sheath of the composite optical fiber is not less than the numerical aperture of the fiber for radiation with the smaller of the wavelengths λ1 and λ2, and the ratio of the refractive indices of materials of the inner cladding and the cladding of a composite optical fiber is not less than the numerical aperture of the fiber for radiation with a larger wavelength λ1 and λ2. 4. The solid-state up-conversion laser according to claim 3, characterized in that the ratio of the diameters of the shells of the composite optical fiber is chosen equal to the ratio of the wavelengths of the pump radiation.

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