RU2637540C1 - Ap-conversion fluorescent nano-glass ceramics - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: fluorescent nano-glass ceramic consists of the following components, moll. %: SiO₂ 41.5-43.5; YbF₃ 1.0-2.5; PbO 12.0-14.5; PbF₂ 32.5-35.0; CdF₂ 7.0-7.5_; Tb₂O₃ 1.0-1.5 and Tm₂O₃ 0.1-0.4. The field of application is optoelectronics, photonics, laser instrument engineering.

EFFECT: producing transparent fluorescent nano-phase ceramic performing ap-conversion converting of infrared radiation into visible blue-green one at lower temperatures of the synthesis and thermal processing of glass.

2 tbl, 1 dwg

Description

The invention relates to optically transparent glass crystalline nanomaterials, namely, to up-conversion luminescent oxyfluoride nanoglassceramics, coactivated by rare-earth ions (REE), and a method for its synthesis. The proposed glass ceramics is coactivated with three REE ions: terbium, thulium, ytterbium and is intended for use as up-conversion phosphors that efficiently convert infrared laser radiation (~ 960 nm) into the visible one, corresponding to the blue and green regions of the color chart according to CIE 1931. Such materials can also find application in infrared visualizers, diode lamps, color displays, fiber laser systems and devices containing solar cells for increase their effectiveness.

Transparent oxyfluoride nanoglassceramics is obtained on the basis of oxyfluoride glass activated by rare-earth ions by heat treatment. During the heat treatment of the initial glass, fluoride nanocrystals activated by REE ions are formed in the glass matrix; as a result, oxyfluoride glass ceramics combines the best properties of low-phonon fluoride nanocrystals, which determine the optical properties of rare-earth ions, and the simplicity of manufacture, and the improved physicochemical properties of the glass oxide matrix.

Known luminescent glass ceramics containing in mol. %: 42 SiO ₂ ; 26Al ₂ O ₃ ; 21 LiF; 11YbF ₃ activated by 0.1EuF ₃ or TbF ₃ [1]. To obtain nanoglassceramics, glass of the specified composition is synthesized at a temperature of 1400 ° C and subjected to heat treatment at a temperature of 630 ° C, as a result of which LiYbF ₄ nanocrystals containing Eu ³⁺ or Tb ³⁺ ions are formed in the glass matrix, causing luminescence in red and green visible spectral regions, respectively. The disadvantage of this glass ceramic is the high-temperature mode of its synthesis and the absence of blue glow.

Known transparent oxyfluoride glass ceramics, coactivated by ions of terbium Tb ⁺³ and ytterbium Yb ⁺³ , composition in mol. %: 47.4 SiO ₂ ; 19 Al ₂ O ₃ ; 28.4 CaF ₃ ; 2TbF ₃ ; 3.2 YbF ₃ [2]. Obtaining the known glass ceramics also requires high synthesis temperatures (1400 ° C) and heat treatment (660 ° C) of the original glass, which increases the energy consumption for its production.

Closest to the proposed composition of luminescent glass ceramics in technical essence and the achieved result is luminescent oxyfluoride glass ceramics (taken as a prototype), which contains in mol. %: 47.4 SiO ₂ ; 19Al ₂ O ₃ ; 28.4CaF ₂ ; xTbF ₃ ; 0.1TmF ₃ ; 3.2YbF ₃ ; (2) GdF ₃ , where x = 0.05; 0.1; 0.2; 0.5 [3]. The synthesis temperature of the initial glass is 1400 ° C, the temperature of the heat treatment at which the precipitation of the nanocrystalline phase CaF ₂ occurs is 650 ° C. The glass-ceramic-prototype is characterized by blue, green and red luminescence, however, the technology for its preparation involves the combined presence in the luminescence spectrum of both red, and blue, and green glow. To obtain blue and green monochrome radiation in this glass-ceramic, it is necessary to use filters that would select radiation with the necessary color characteristics. In addition, this glass ceramic is also synthesized according to the high-temperature regime.

The technical task of the invention is the creation of transparent nanophase glass ceramics, which performs the up-conversion conversion of infrared radiation into visible blue-green while lowering the synthesis temperature and heat treatment of glass.

This object is achieved in that the luminescent nanoglass ceramic includes SiO ₂ , YbF ₃ and is characterized in that it additionally contains PbO, PbF ₂ , CdF ₂ , Tb ₂ O ₃ and Tm ₂ O ₃ in the following ratio of components, mol. %: SiO ₂ 41.5-43.5; YbF ₃ 1.0-2.5; PbO 12.0-14.5; PbF ₂ 32.5-35.0; CdF ₂ 7.0-7.5; Tb ₂ O ₃ 1.0-1.5 and Tm ₂ O ₃ .0.1-0.4. The quantitative ratio of these components and the additional content of PbO, PbF ₂ , CdF ₂ , Tb ₂ O ₃ and Tm ₂ O ₃ can provide a blue-green glow, reduce the temperature of glass synthesis by 500 ° C, heat treatment temperature by 250 ° C and create a new Up-conversion luminescent nanoglassceramics for phosphors of the blue-green visible region of the spectrum.

From sources of information, luminescent nanoglassceramics with a given ratio of components and an additional content of PbO, PbF ₂ , CdF ₂ , Tb ₂ O ₃ and Tm ₂ O ₃ for solving this problem is unknown and is proposed by us for the first time.

Silicon dioxide (amorphous), lead oxide, lead fluoride, cadmium fluoride grade “hch”, ytterbium fluoride, terbium and thulium oxides (99.99%) are used as raw materials for glass synthesis. Raw materials are weighed on an electronic balance, mixed thoroughly and sieved through a No. 0.5 sieve. Thus prepared mixture for melting the glass is poured into corundum crucibles, which are placed in a glass melting electric furnace with silicon heaters. Glass is melted in an air atmosphere at a temperature of 900 ± 50 ° С with holding at a maximum temperature for 30 minutes until complete penetration and clarification of the glass melt. The rate of temperature rise in the furnace is 300 ° C per hour. Samples (functional elements for laser systems and phosphors) are made from finished glass melt, which are annealed at a temperature of 350 ° C to relieve internal stresses.

Up-conversion luminescent nanoglassceramics is obtained by crystallization of the original glass. Glass is heat-treated at a temperature of 400 ° С for 15 or 45 hours. During the heat treatment of the initial glass, lead fluoride nanocrystals containing rare-earth ions Tb, Tm, and Yb (Tb, Tm, Yb: PbF ₂ ) are formed in the glass matrix. The average crystal size is 5-10 nm. By varying the duration of heat treatment of the original glass without changing its chemical composition, it is possible to control and smoothly rearrange the color characteristics of the luminescence of glass ceramics from blue to green.

Specific compositions and properties of the proposed glass ceramics and prototype are presented in tables 1, 2.

Glass ceramic compositions

Compositions located outside the claimed area cannot be used for this purpose, since during heat treatment they lose their transparency.

Glass ceramic properties

The invention is illustrated in the drawing.

FIG. 1 - The spectrum of up-conversion luminescence of the proposed nanoglassceramics when excited at a wavelength of 960 nm.

In FIG. Figure 1 shows the spectrum of up-conversion luminescence of the original glass and heat-treated at a temperature of 400 ° C and different heating times of 15 hours and 45 hours. Changing the heat treatment mode of the glass, namely its duration, leads to a redistribution of the intensities of the up-conversion luminescence bands of nanoglassceramics, which causes a change its color characteristics from blue to green.

The advantage of the inventive glass ceramics is significantly lower temperatures for the synthesis and heat treatment of the original glass, which reduces the energy consumption for its production, and also allows you to get blue and green monochrome radiation.

Thus, the transparent oxyfluoride nanoglassceramics of the proposed composition is capable of converting infrared laser radiation into visible and has intense up-conversion blue and green luminescence, which makes it possible to effectively use it for phosphors of the blue and green spectral regions.

Information sources

1. Optical spectroscopy of Eu ³⁺ and Tb ³⁺ doped glass ceramics containing LiYbF ₄ nanocrystals / Chen Daqin, et al // Appl. Phys. Lett. 94, 041909, 2009.

2. Intense ultraviolet emission from Tb ³⁺ and Yb ³⁺ codoped glass ceramic containing CaF ₂ nanocrystals / Lihui Huang, et al // Appl. Phys. Lett. 90, 131116, 2007.

3. Upconversion Luminescence with Adjustable Multi-Color in Rare Earth Co-Doped Transparent Oxyfluoride Glasses / Z. Song, et al // Symposium on Photonics and Optoelectronics (SOPO) - IEEE, 2012. - P. 1-3 (prototype).

Claims (2)

Up-conversion luminescent nanoglassceramics, including SiO ₂ , YbF ₃ , characterized in that it further comprises PbO, PbF ₂ , CdF ₂ , Tb ₂ O ₃ and Tm ₂ O ₃ in the following ratio of components, mol. %: SiO ₂ 41.5-43.5 Ybf ₃ 1.0-2.5 Pbo 12.0-14.5 Pbf ₂ 32.5-35.0 Cdf ₂ 7.0-7.5 Tb ₂ O ₃ 1.0-1.5 Tm ₂ O ₃ 0.1-0.4

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