RU2777301C1 - Luminescent silver halide light guide - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to luminescent materials, namely, to luminescent silver halide light guides designed as an advanced active medium in the manufacture of fibre lasers of the near and medium infrared ranges. Luminescent silver halide light guide contains silver halide ceramics of the composition AgCl_0.2Br_0.8, alloyed with oxides of rare earth elements, with the following ratio of ingredients, % wt.: AgCl_0.2Br_0.8 97.0 to 99.0; oxide of a rare earth element 3.0 to 1.0.

EFFECT: ensured generation during pumping in the near and medium IR spectral regions at room temperature.

4 cl, 1 dwg, 2 ex

Description

The invention relates to luminescent materials, namely to luminescent silver halide light guides, intended as a promising active medium in the manufacture of fiber lasers in the near and medium infrared range.

Known luminescent crystals based on silver bromide doped with praseodymium and erbium ions [D. Bunimovich, L. Nagli, A. Katzir, “Luminescence properties of praseodymium- and erbium-doped silver bromide crystals,” Applied Optics, Vol. 36, no. 30, 1997, P. 7708-7711]. The luminescence of crystals was studied in the visible and near infrared (IR) regions of the spectrum at low temperatures - liquid nitrogen and helium. It has been established that ions of rare earth elements, such as neodymium (Nd), praseodymium (Pr), and erbium (Er), can be effectively incorporated into silver halides and cause luminescence in the range from 550 to 2520 nm in AgBr crystals when pumped at a wavelength of 489 nm. doped with PrCl ₃ . But luminescent silver halide crystals are known, rather than luminescent silver halide light guides. In addition, luminescence spectra have been studied at low temperatures, and practical applications require optical materials that luminesce at room temperature. The quenching of luminescence bands at elevated temperatures can be explained by an insufficient amount of dopant in the matrix.

Known silver halide crystals composition AgCl _0.77 Br _0.23 and AgBr crystals doped with PrCl ₃ [L. Nagli, A. German, A. Katzir, “Spectroscopic studies of Pr ³⁺ ions in silver halide crystals,” Applied Optics, Vol. 39, no. 27, 2000, P. 5070-5075]. Crystal luminescence was also studied in the visible and infrared regions of the spectrum at liquid nitrogen and helium temperatures. A strong dependence of the spectroscopic properties of Pr ³⁺ ions on the composition of the silver halide crystal was revealed. Long-wavelength IR luminescence bands up to 2520 nm, which have a high quantum yield upon pumping at a wavelength of 591 nm, were discovered for the first time in silver halide crystals. But the luminescence was determined, firstly, in AgCl _0.77 Br _0.23 crystals, and not in optical fibers, and secondly, the study was also carried out at low temperatures, and as it was increased, quenching of some luminescence bands was observed. This effect can be explained by the dependence of the amount of the doping component PrCl ₃ on the composition of the silver halide crystal AgCl _x Br _1-x .

Known silver halide crystals of the same system AgCl-AgBr composition AgCl _0.5 Br _0.5 doped with dysprosium chloride DyCl ₃ in the amount, wt.%: 0.05, 0.1 and 0.3 [AG Okhrimchuk, AD Pryamikov, KN Boldyrev, LN Butvina , E. Sorokin, “Collective phenomena in Dy-doped silver halides in the near- and mid-IR,” Optical Materials Express, Vol. 10, no. 11, 2020, 2834-2848]. The luminescence of AgCl _0.5 Br _0.5 : Dy crystals in the near and mid-IR ranges was also studied at low temperatures. It is concluded that crystals are a promising active medium for generating oscillations at wavelengths of 3.0 μm and 4.3 μm when pumped at a wavelength of 1.3 μm. It is noted that when polycrystalline fibers are obtained from crystals by hot extrusion, it is possible to develop a fiber laser in the mid-IR range.

But luminescent crystals are known, and not light guides, in which the maximum luminescent emission was observed at low temperatures of liquid nitrogen. It should be noted that luminescence in crystals doped specifically with REE chlorides is observed due to the luminescence of ions (Dy ³⁺ , Nd ³⁺ , Er ³⁺ , etc.), and not due to oxobromides of rare earth elements (NdOBr, YbOBr, DyOBr), how it is carried out in the developed luminescent light guides. In addition, for practical application, the luminescent properties must be fixed at room temperature both in luminescent crystals and in optical fibers.

There is a technical problem in the development of a luminescent crystalline fiber doped with rare earth elements (REE), luminescent at room temperature, transparent from 2.0 to 20.0 μm, plastic and non-hygroscopic, intended as an active medium in the manufacture of fiber lasers in the near and mid-IR range .

The solution to the problem is achieved due to the fact that the luminescent silver halide light guide, characterized in that it contains a silver halide ceramic composition AgCl _0.2 Br _0.8 doped with oxides of rare earth elements, in the following ratio of ingredients, wt.%:

AgCl _0.2 Br _0.8 -97.0 - 99.0 rare earth oxide -3.0 - 1.0

2. Luminescent silver halide light guide according to claim 1, characterized in that dysprosium oxide is used as a dopant.

3. Luminescent silver halide light guide according to claim 1, characterized in that neodymium oxide is used as a dopant.

4. Luminescent silver halide light guide according to claim 1, characterized in that ytterbium oxide is used as a dopant.

The developed luminescent silver halide light guide has an advantage over known analogues:

1. A luminescent light guide doped with oxides of rare earth elements, luminescing at room temperature, and not luminescent crystals doped with REE chlorides, luminescing at low temperatures (liquid nitrogen) has been created.

2. Efficient luminescence in optical fibers is observed at room temperature due to luminescence centers - oxobromides DyOBr, NdOBr, YbOBr in an amount of 1.0 - 3.0 wt.%, and not due to rare earth ions, which are introduced into the composition of AgCl _0.77 Br crystals _0.23 and AgCl _0.5 Br _0.5 in the form of chlorides in the amount of 0.01, 0.05, 0.1 and 0.3 wt.%.

The essence of the invention lies in the fact that a new luminescent silver halide light guide for the near and mid-infrared range, made of silver halide ceramics doped with oxides of rare earth elements, has been developed. Ceramics based on a solid solution of composition AgCl _0.2 Br _0.8 doped with an optimal amount of 1.0 to 3.0 wt.% oxides of dysprosium, or neodymium, or ytterbium, is obtained by the method of thermozone crystallization-synthesis - hydrochemical method [L. V. Zhukova, D. D. Salimgareev, A. S. Korsakov, A. E. Lvov, L. V. Zhukova, Promising terahertz materials: crystals and ceramics: textbook. LLC "Publishing House UMC UPI", 2020, 308 p.]. In this case, REE oxides are embedded in the AgCl _0.2 Br _0.8 matrix in the form of DyOBr, or YbOBr, or NdOBr oxobromides, which are the centers of luminescence - luminescence at room temperature. In light guides obtained by extrusion from such ceramics, oxobromides of rare earth elements 2 with a size of 20-100 nm are distributed in matrix 1 (Fig. 1. Nanostructure of the end face of a luminescent silver halide light guide). The light guide transmits in the range from 2.0 to 20.0 μm, it is plastic and non-hygroscopic, since its main composition is water-insoluble and plastic silver halides (see examples). The choice of the optimal amount of REE is based on the results of mathematical modeling and confirmed by experimental studies.

Example 1

Using the extrusion method from ceramic doped with one of three types of oxides of rare earth elements, a light guide was made with the composition, in wt.%:

Using the method of scanning electron microscopy, the nanostructure of the end of the light guide was removed, in which oxobromides of rare earth elements are the centers of luminescence - luminescence (Fig. 1).

On a Shimadzu IR Prestige-21 spectrophotometer (1.28 - 41.7 μm), transmission spectra were taken in the infrared region for three types of luminescent light guides. Light guides transmit in the spectral range from 2.0 to 20.0 μm with transparency up to 70%.

The fiber doped with Dy ₂ O ₃ , when pumped by a diode laser at a wavelength of 1.08 μm, generates at room temperature in the mid-IR region at wavelengths of 2.4 μm, 4.5 μm, 5.5 μm.

The fiber doped with Nd ₂ O ₃ , when pumped by a diode laser at a wavelength of 807 nm, generates (luminesces) at room temperature in the near and mid-IR regions at wavelengths of 1.06 μm, 4.5 μm, 5.0 μm and 6, 5 µm.

The fiber doped with Yb ₂ O ₃ when pumped by a diode laser at a wavelength of 970 nm generates at room temperature in the near infrared region at a wavelength of 1.07 μm.

Example 2

Luminescent fibers were produced by extrusion, as in example 1, the composition in wt.%:

For three types of luminescent light guides, the transmission spectra were taken in the IR range. They are transparent up to 70% in the spectral range from 2.0 to 20.0 µm. The nanostructure of the end face of a luminescent light guide is shown in Fig. one.

Light guides are generated at room temperature when they are pumped by diode lasers.

For a fiber doped with Dy ₂ O ₃ , pumping is at 1.08 µm. generation - at 2.4 µm, 4.5 µm, 5.5 µm.

For a fiber doped with Nd ₂ O ₃ , pumping is at a wavelength of 807 nm, generation is at a wavelength of 1.06 μm, 4.5 μm, 5.0 μm, 6.5 μm.

For a fiber doped with Yb ₂ O ₃ , pumping is at 970 nm, generation is at 1.07 μm.

Example 3

Received luminescent silver halide light guides, as in example 1, the composition in wt.%:

Three types of luminescent light guides transmit in the range from 2.0 to 20.0 µm with transparency up to 70%. The nanostructure of the end face of a luminescent light guide is shown in Fig. one.

As in example 1, the fibers luminesce at room temperature in the near and mid-IR regions when they are pumped by diode lasers.

When the content of Dy ₂ O ₃ , or Yb ₂ O ₃ , or Nd ₂ O ₃ in the silver halide matrix of the composition AgCl _0.2 Br _0.8 is less than 1 wt.%, it is not possible to register luminescence in fibers at room temperature, and if the REE content is more than 3 wt.% , then some luminescence spectra in the fibers are quenched. In addition, the transmission range narrows and the transparency decreases to 40 - 60%.

Technical result

New luminescent silver halide fibers have been developed that, when pumped, generate in the near and mid-IR spectral regions at room temperature, which is an important factor for practical applications. Light guides are intended as a promising active medium for manufacturing a new class of fiber lasers in the near and mid-IR range.

Claims (5)

1. Luminescent silver halide light guide, characterized in that it contains a silver halide ceramic composition AgCl _0.2 Br _0.8 doped with oxides of rare earth elements, in the following ratio of ingredients, wt.%: AgCl _0.2 Br _0.8 97.0-99.0 rare earth oxide 3.0-1.0 2. Luminescent silver halide light guide according to claim 1, characterized in that dysprosium oxide is used as a dopant. 3. Luminescent silver halide light guide according to claim 1, characterized in that neodymium oxide is used as a dopant. 4. Luminescent silver halide light guide according to claim 1, characterized in that ytterbium oxide is used as a dopant.

Images