RU2700069C1 - Anti-stokes luminophore for imaging infrared laser radiation - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to laser engineering and can be used in alignment of laser systems, analysis of radiation intensity distribution in a laser beam, as well as for protection of currency and security papers. Anti-Stokes luminophore for imaging infrared laser radiation is obtained by mixing powders of anti-Stokes luminophore F(a)CD-546-2 in amount of 1–99 wt% and fluoride luminophore with fluorite structure – the rest. Fluoride luminophore composition corresponds to formula M_1-xHo_xF_2+x, where M is selected from a group consisting of Ca, Sr and Ba taken separately or together; 0.01≤x≤0.90.

EFFECT: said luminophore is capable of inertia-free conversion of infrared laser radiation in the spectral range of wavelengths 780–1,650 nm and 1,850–2,150 nm into luminescence of the visible wavelength range at high resolution.

1 cl, 1 tbl, 3 dwg

Description

The invention relates to laser technology, in particular to materials for visualizing laser radiation fields, and can be used in aligning laser systems, analyzing the distribution of radiation intensity in a laser beam, and also for protecting banknotes and securities.

Among industrial materials, the anti-Stokes phosphor based on Y (yttrium), La (lanthanum), La (lanthanum), Gd (gadolinium), Lu (lutetium) activated ions, activated by Ho ³⁺ ions (holmium) and sensitized by Yb ³⁺ ions (ytterbium), whose chemical composition is known is described by the following generalized chemical formula: (SE _1-xy ) ₂ O ₂ S: Yb _x Ho _y , where SE is Y, La, Gd, Lu, 0.01 <x <0.8; 0.0001 <y <0.1 (EP 1896551, IPC C09K 1/77, publ. 10.12.2008).

The main disadvantage of the anti-Stokes phosphor for use as visualizers is the small spectral range of infrared laser radiation (0.94-0.98 μm), which is converted into a visible cure.

A known mixture for producing anti-Stokes phosphor based on the oxides Y, Zn (zinc), Ba ²⁺ (barium carbonate), including oxides Y, Zn, Yb ³⁺ , Er ³⁺ (erbium), Ba ²⁺ , additionally containing as mineralizers BaCl ₂ (barium chloride) and BaF ₂ (barium fluoride) in a ratio of 1: 1 in an amount of 3-7 wt. % of the mass of the charge (RU 2015147841, IPC S09K 11/00, publ. 11.05.2017).

Also known is a phosphor of the complex principle of action based on rare-earth oxysulfides activated by Ho ³⁺ ions and sensitized by Yb ³⁺ ions, which has a chemical composition,

corresponding to the following empirical formula: (Ln _1-xydc Yb _x Ho _y Me ¹ _d Me ² _c ) ₂ O ₂ S, where Ln is at least one of Y ³⁺ , La ³⁺ , Gd ³⁺ ; Me ¹ - one of the ions of the elements of group II of the Periodic system - Ca ²⁺ (calcium), Sr ²⁺ (strontium), Ba ²⁺ (barium); Me ² is one of the ions of elements IV (Ti ⁴⁺ (titanium), Zr ⁴⁺ (zirconium), Si ⁴⁺ (silicon)) or V (Nb ⁵⁺ (niobium), Ta ⁵⁺ (tantalum)) of the Periodic Table ; 0.01 х x 0 0.2; 0,0005≤y≤0.01; 0.01 d d 0 0.1; 0.005≤s≤0.05 (RU 2614688, IPC С09К 11/84, publ. 03/28/2017).

The disadvantages of the known phosphors is the limited spectral range of conversion of infrared laser radiation into the luminescence of the visible wavelength range.

The closest technical solution to the claimed invention is a green anti-Stokes phosphor based on oxysulfide Y, activated by Er ³⁺ ions and sensitized by ytterbium ions Yb ³⁺ , having the chemical formula Y ₂ O ₂ S: Yb, Er. The phosphor was developed by NPF LUM LLC, and has been manufactured by the industry since 1982 under the brand name Ф (а) СД-546-2 (Manashirov O.Ya. et al. Status and prospects of development of anti-Stokes phosphors for infrared visualizers from 0.8- 13 microns. // RAS. Inorganic materials. 1993. V. 29. No. 10. S. 1322-1325).

Due to its high quality, the well-known anti-Stokes phosphor of green color is still widely used in Russia and abroad in various fields of technology. The phosphor has a sufficiently high energy efficiency for converting infrared radiation in the range of 780-1600 nm into a visible glow and has the necessary technological, operational and chemical parameters for practical use. A disadvantage of the known solution is the inability to visualize infrared radiation in the spectral range above 1600 nm.

The technical result consists in the creation of anti-Stokes phosphor capable of inertialess visualization of infrared

radiation in a wide spectral range of wavelengths of infrared radiation of 780-1650 nm and 1850-2150 nm with high resolution.

The indicated technical result is achieved due to the phenomenon of interaction of excited Yb ³⁺ , Er ³⁺ ions in the anti-Stokes phosphor of brand Ф (а) СД-546-2 and Ho ³⁺ ions in a fluoride phosphor with a fluorite structure doped with Ho ³⁺ ions, whose composition corresponds to the following formula:

M _1-x Ho _x F _{2 + x} ,

where M is selected from the group consisting of Sr, Ca, Ba, taken separately or together, and where the values of the indices x of the elements that make up the compound satisfy the condition 0.01≤x≤0.90, to visualize laser radiation in the range of lengths waves of 780-1650 nm and 1850-2150 nm in the visible range.

The essence of the invention lies in the fact that the anti-Stokes phosphor for visualizing infrared laser radiation obtained by mixing powders of an anti-Stokes phosphor brand F (a) SD-546-2 and a fluoride phosphor with a fluorite structure doped with But ³⁺ ions, the composition of which corresponds to the following formula:

M _1-x Ho _x F _{2 + x} ,

where M is selected from the group consisting of Sr, Ca, Ba, taken separately or together, and where the values of the indices x of the elements that make up the compound satisfy the condition 0.01≤x≤0.90, converts infrared laser radiation in the spectral range wavelengths of 780-1650 nm and 1850-2150 nm in the luminescence of the visible range of wavelengths.

In the table. 1 presents the lighting characteristics of anti-Stokes phosphor. In FIG. 1 shows the luminescence spectrum of the anti-Stokes phosphor in the visible spectral range when excited by laser radiation with a wavelength of 972 nm, FIG. 2 - luminescence spectrum of anti-Stokes phosphor upon excitation

laser radiation with a wavelength of 1532 nm, in FIG. 3 - luminescence spectrum of anti-Stokes phosphor when excited by laser radiation with a wavelength of 1912 nm.

The following materials are used to prepare the anti-Stokes phosphor:

- Anti-Stokes phosphor of brand F (a) SD-546-2 produced by CJSC NPF Luminofor (Stavropol, Russia). Main characteristics: average particle size 10-15 microns, effective excitation region 0.94-1.65 microns.

- Fluoride powder with a fluorite structure doped with But ³⁺ ions, developed by PhotonTechSystem LLC (Saransk, Russia). Main characteristics: average particle size of 0.14 microns, effective excitation region of 1.8-2.15 microns.

The claimed invention is illustrated by the following example.

Example. To prepare the anti-Stokes phosphor, powders of the anti-Stokes phosphor of brand F (a) SD-546-2 and a fluoride phosphor with a fluorite structure doped with But ³⁺ ions taken in the ratio x: y are used, where x: 1≤x≤99; y = 100s, which are then mixed.

The spectral range of operation of the anti-Stokes phosphor is determined using the reflection spectra of the phosphor recorded on a Perkin Elmer Lambda 950 scanning two-beam spectrophotometer and by excitation of the obtained anti-Stokes phosphor with infrared laser radiation sources at wavelengths of 800 nm, 900 nm, 972 nm, 1064 nm, 1460 nm, 1532 nm, 1857 nm, 1912 nm, 1940 nm and 2064 nm.

The quantum yield of luminescence is determined using the absolute method of measuring the quantum yield. To implement this technique, an assembly has been assembled consisting of the integrating sphere OL IS-670-LED, spectroradiometer OL-770 UV / VIS and spectrometer M833 (Solar LS).

The sensitivity of the phosphor is defined as the minimum power density of the incident laser radiation at which luminescence of the phosphor is still observed in the visible wavelength range. The sensitivity of the visualizer depends on the wavelength of the incident radiation.

The destruction threshold is determined using visual fixation of the destruction of the phosphor. The phosphor is irradiated with laser radiation at wavelengths of 800 nm, 972 nm, 1460 nm, 1532 nm and 1912 nm. Starting from a certain value of the power density of the incident radiation, the sample begins to collapse and combustion products appear. This value of the excitation power density is taken as the threshold for the destruction of the phosphor. The laser radiation power is measured using a power meter 11 PMK-30N-H5.

From the analysis of the data presented in table. 1 it follows that when the anti-Stokes phosphor is irradiated with infrared radiation in the spectral range of wavelengths of 780-1650 nm and 1850-2150 nm, it has intense luminescence in the visible range of the spectrum (Fig. 1-3).

During testing, it was found that the ratio of the phosphor powders used in the invention slightly affects the quantum yield of luminescence in the entire spectral range of the visualizer, which is associated with the high efficiency of the conversion of infrared laser radiation into a visible glow by the original phosphors.

Compared with the known anti-Stokes phosphor, the claimed solution allows inertialess visualization of infrared radiation in a wide range of infrared wavelengths of 780-1650 nm and 1850-2150 nm with a high contrast of the observed pattern of distribution of infrared radiation and high resolution.

Claims (4)

Anti-Stokes phosphor for visualizing infrared laser radiation obtained by mixing powders of anti-Stokes phosphor grade Ф (а) СД-546-2 and fluoride phosphor with the structure of fluorite doped with But ³⁺ ions, the composition of which corresponds to the following formula: M _1-x Ho _x F _{2 + x} , where M is selected from the group consisting of Ca, Sr and Ba taken separately or together, and where the values of the indices x of the elements included in the compound satisfy the condition 0.01≤x≤0.90, converts infrared laser radiation in the spectral range wavelengths of 780-1650 nm and 1850-2150 nm in the luminescence of the visible range of wavelengths, with the following ratio of components, wt.%: Anti-Stokes Phosphor brand F (a) SD-546-2                                      1-99 Fluoride phosphor with structure fluorite doped with ions But ³⁺ rest.

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