RU2717158C1 - INORGANIC POLYCRYSTALLINE SCINTILLATOR BASED ON Sc, Er:YAG AND A METHOD FOR PRODUCTION THEREOF - Google Patents

Abstract

FIELD: manufacturing technology.SUBSTANCE: present invention relates to the field of transparent ceramic materials with a yttrium-aluminum garnet structure doped with erbium and scandium ions of a cubic structure Er:YAG(Sc), having properties for use as luminescent scintillation materials, intended for scanning systems of medical high-speed computed tomography, x-ray units and gamma radiation plants. Initial solution of yttrium, aluminum, erbium and scandium chlorides is prepared, evaporated to concentrated state, sprayed in solution of settling agent – basic solution of aqueous ammonia to obtain precipitate – precursor. Filtered precipitate having a homogeneous composition of the cubic solid solution is dried and calcined at temperature in range from 800 to 1,000 °C, is pressed by isostatic compaction into compact of preset shape with density of 55 % of theoretical density. Further, obtained compact is sintered in vacuum at temperature of 1,700–1,750 °C, degree of vacuum of 10Pa.EFFECT: obtaining transparent ceramics with light transmission of up to 85 % and improved scintillation parameters: irradiation area 540–700 nm, light output 56–74 % relative to CsI:Tl, pulse duration 53–44 ns.4 cl, 5 dwg, 1 tbl, 3 ex

Description

FIELD OF THE INVENTION

The present invention relates to the field of ceramic materials, and more specifically, to improved rare-earth alloying of ceramic luminescent scintillation materials with the structure of yttrium-aluminum garnet, which are especially useful for use in scanning systems of medical high-speed computer tomography, with other x-rays, gamma radiation, as well as for radiation detection purposes.

State of the art

Solid state scintillation materials have long been used as radiation detectors to detect penetrating radiation, like X-ray counters. Recently, such detectors have played an important role in computed tomography, digital radiography, other x-rays, gamma radiation, ultraviolet radiation, as well as for applications to detect radiation. Solving the problems of ensuring radiation safety of the environment, nuclear medicine, X-ray computed tomography, and a number of others, related to the development of nuclear instrument engineering and high-energy physics, requires an increase in the number of scintillation materials. The applicability of one or another oxide single-crystal scintillator is determined by the combination of its luminescent, scintillation, optical and physico-chemical properties. The prospects for the development of high-energy physics and nuclear medicine are expanding in connection with the development of polycrystalline oxide materials with a certain light output, short exposure times and insignificant afterglow. The operating conditions of scintillators in high-energy radiation detectors require, first of all, significant absorption capacity and speed. To create modern devices in which the scintillator is combined with a solid-state photodiode, the lower limit of the area of crystal emission should be at 650 nm. In order to extract all the luminescent light generated in the luminescent material, the luminescent material must be transparent. Otherwise, most of the luminescent light will not reach the photosensitive detector due to scattering and absorption within the luminescent material. In order to meet the requirements for the scintillator, the material must have uniform optical and luminescent properties, and the properties of the radiation absorption source along its entire length. To obtain activated scintillation single crystals, it is required to grow the initial boules, which have a uniform concentration of the luminescent activator, both in the radial direction and in the longitudinal direction of the boule, since the luminescent yield depends on the local concentration of activator ions.

Only two single-crystal phosphors are known to be used in systems of commercial X-ray converters - cesium iodide (CsI) and cadmium tungstate (CdWO ₄ ). Scintillators based on cesium iodide crystal (CsI) have high scintillation efficiency, however, they have very low chemical stability, are soluble in alcohol and weak inorganic acids. In addition, crystals of cesium iodide (CsI) and cadmium tungstate (CdWO ₄ ) are highlighted in response to x-ray stimulation from 0.3 to 1.2 μs. A polycrystalline alternative to cesium iodide and cadmium tungstate is described in patent applications US 4421671, 4466929; 4,466,930; 4,473,413; 4,518,545; 4,518,546; 4,525,628; 4,571,312; 4747973 and 4783596. The solid state scintillation materials described in these applications are cubic yttrium-gadolinium oxide and yttrium is an aluminum fan with additives of various rare earth elements to provide the scintillation material with the required luminescent properties. This polycrystalline material has a significant advantage compared with cesium iodide and cadmium tungstate: the absence of radiation damage and hysteresis. However, the disadvantage of scintillation compositions with cubic syngony is a sufficiently low afterglow of up to 0.5 μs, and this is not enough to satisfy the requirements for a high-quality scanning system. In addition, this polycrystalline material has a primary decay time of the order of 1000 μs - not as fast as required for existing scanning systems.

DE 3704813 A1 discloses a single crystal scintillator Gd _3-X Ce _X Al _5-Y Sc _Y O ₁₂ (X = 0.05-0.2; Y = 0.5-2.5) obtained by spray drying a solution of sulfate of the starting components, calcining the dried sulfate, mixing the oxides, followed by pressing, sintering, melting and drawing a single crystal in high vacuum. The spectrum for the luminescent yield of this material contains a peak in the region of 560 nm. A significant drawback of the Gd _3-X Ce _X Al _5-Y Sc _Y O ₁₂ single-crystal scintillator (X = 0.05-0.2; Y = 0.5-2.5) is the low light output of the crystal's fast glow: 10% from that for the most widely used CsI: Tl scintillator, with a short emission time of 65-100 ns.

Closest to the claimed invention and selected as a prototype, is a method for producing transparent ceramics based on gallium-gadolinium garnet (GGG), gallium-scandium-gadolinium garnet (GSP) and yttrium-aluminum garnet (YAG) doped with rare earth ions Cr ^{3 +} , Ce ³⁺ , Nd ³⁺ and a scintillator based on this ceramic (Patent US 5484750 A1 GENERAL ELECTRIC COMPANY 01/16/1996). A known method for producing transparent ceramics based on cubic structures of pomegranate is to mix the initial solution of chloride salts of the desired cations with an aqueous solution of ammonium hydroxide to obtain a precipitate having a uniform composition. This precipitate is separated from the solution, dried, thermally decomposed at a temperature in the range from 700 to 1000 ° C, pressed by isostatic pressing into a semi-finished product with a density of 45% of theoretical density. Next, the resulting semi-finished product is sintered in an oxygen atmosphere at a temperature of from 1400 to 1700 ° C, then sintered by hot isostatic pressing at high pressure and a temperature of 1400-1600 ° C, to obtain the desired light transmission (up to 78%). The main scintillation parameters of ceramics based on cubic garnet structures obtained by this method are: light output 16-36% relative to the light output CsI: Tl (C _rel ); the luminescence time is 82-95 ns.

The disadvantage of this method is the complexity of the manufacturing process associated with the need for two operations of sintering in oxygen atmosphere at a temperature of 1700 ° C, and hot isostatic at high pressure and a temperature of 1600 ° C, as well as low light output of fast luminescence of ceramics: 16% of that for the most widely used CsI scintillator: Tl. Also, the use of Cr ^3+, Се ³⁺ as transition metal alloying ions does not allow obtaining a scintillator based on yttrium-aluminum garnet with high light output - according to the prototype 39-43%.

Disclosure of Invention

The aim of the present invention is to provide a ceramic scintillation material for ionizing radiation detectors based on activated yttrium-aluminum garnet, illuminating in the wavelength range 550-700 nm, having short luminescence times and high light output, as well as a method for producing such a material in the form of a transparent ceramic light transmission in the wavelength range of 400-1100 nm to 85%.

The technical problem solved by the present invention is to create a scintillation material based on polycrystalline yttrium-aluminum garnet (Y ₃ Al ₅ O ₁₂ ) doped with erbium ions (0.5 at.% With respect to the yttrium atom), containing as activating trivalent scandium additives in an amount of 10.0-20.0 at. %, with improved scintillation parameters. Illumination area 550-650 nm; light output 45-74% relative to CsI: Tl; flashing time 55-60 ns. As an activating additive for polycrystalline yttrium aluminum garnet doped with Er: YAG ions, Sc ^{3+ is used,} which was not previously used for Er: YAG scintillators in this quality.

The specified technical result is achieved due to the fact that the scintillation material for detecting ionizing radiation, consisting of polycrystalline yttrium-aluminum garnet doped with Er ³⁺ , contains an activating additive of scandium oxide in the amount of 10.0-20.0 at. %, with the formation of solid solutions in accordance with the general formula: Y _3-n-0.4m Er _n Sc _m Al _5-0.6m O ₁₂ (n = 0.015; m = 0.3-0.6); The production method, including dissolving the starting cations in the form of chlorides in hot deionized water, is evaporated to a concentrated state and then using the heterophase coprecipitation method by spraying into a precipitator. The precipitant is prepared as follows. A solution of carbon ammonium salts in 25% concentration at 25 ° C is preliminarily prepared. Then the resulting solution of carbon ammonium salts of 25% concentration is mixed with a 25% solution of ammonium hydroxide in a volume ratio of 1: 1. During precipitation, a 100% excess of precipitant is used with respect to the stoichiometric amount of cations in the solution from the chlorides, and a precursor powder of a given composition is synthesized. As a result, a precursor powder is obtained that is phase-pure, represented by a cubic solid solution of yttrium-aluminum garnet isomorphically substituted with erbium and scandium oxides in the form of rounded spherical particles. After synthesis, the resulting powder is heated in air to a temperature of 1000 ° C for thermal decomposition, then it is ground in ethanol in the presence of a plasticizer, such as polyvinyl alcohol, followed by drying to obtain granules. After granulation, the powder is formed by isostatic pressing at pressures up to 200 MPa to obtain samples with a relative density of 55%, then it is heat treated in an inert gas at 800 ° C for 4 hours, followed by vacuum sintering at a temperature of 1700-1750 ° C for 15 hours. After vacuum sintering, the samples are subjected to thermal annealing in air at a temperature of 1400 ° C for 5 hours in order to convert Er ^{2+ ions} to Er ³⁺ and to fill the oxygen deficiency. After annealing, the samples are mechanically ground to a thickness of 1.5 mm and polished with diamond pastes. Er: YAG (Sc) ceramics, thus obtained, is an optically transparent material with a cubic structure, with a density of 99.99% of theoretical and a transmittance of 85% in the visible spectrum. The main scintillation parameters are: the area of emission 540-700 nm with two maxima 557 nm and 680 nm; light output 56-74% relative to CsI (Tl); the duration of the scintillation pulse is 53-44 nsec.

The inventive interval activating additives Sc ³⁺ 10,0-20,0 at. % due to the fact that at a concentration less than 10.0 at. % sharply decreases the light output of ceramics (up to 7-5%), and at a concentration greater than 20.0 at. % no further increase in the light output is observed, and therefore, an increase in the concentration of Sc ³⁺ becomes impractical.

The implementation of the invention

The class of scintillation materials is based on activated luminescence of cubic garnet crystals. Grenades are a class of materials with the chemical formula A ₃ B ₅ O ₁₂ . The crystalline structure is cubic, 160 ions in a unit cell containing eight formula units. In accordance with the present invention, cations A are yttrium ion or activators in combination with rare earth ions. Cations B are aluminum ions or, in combination and / or with substitutions of other ions with activators. In particular, we found that with activator ions arranged in eighth coordination or sixth coordination, yttrium-aluminum garnet is luminescent in response to x-ray stimulation. A particularly important X-ray activator ion is Sc ³⁺ , which is located in six coordinated regions.

The luminescent properties of Sc ³⁺ in yttrium-aluminum garnet doped with Er ³⁺ erbium ions are characteristic when the Sc ³⁺ ion is located at the lattice sites, where the crystal field is relatively strong.

In accordance with the present invention, the manufacturing process of a polycrystalline yttrium-aluminum garnet doped with Er ³⁺ ions (0.015 mol% in terms of erbium oxide) containing an activating additive of scandium oxide in an amount of 10-20 at. %, carried out as follows. An initial solution of the desired cations of a given composition is formed by dissolving the yttrium, aluminum, erbium and scandium chlorides in deionized water with heating and evaporated to a concentrated state. Then a hot concentrated solution of cation chloride is sprayed into the precipitant. Upon contact between the two solutions, a precipitate instantly forms from small spherical particles, which are present in the form of a colloidal suspension of the precipitate. Next, the precipitate is decanted in deionized water. The decantation process removes excess ammonium hydroxide and ammonium carbonate and reaction products, in the form of ammonium chloride, from the precipitate. Then the precipitate is separated from the wash solution by filtration. The precipitate is dried at a temperature of 90-110 ° C by vacuum drying for 2 hours. The dried precipitate is calcined in air at a temperature of 1000 ° C for 2 hours for thermal decomposition and the formation of the crystalline structure of a cubic solid solution based on yttrium-aluminum garnet.

The specific surface area of the obtained powders with a garnet structure was measured by the nitrogen absorption method according to the BET method, and varied from 8 to 20 m ² / g. The sizes of crystallites with a garnet structure, measured using scanning electron microscopy, ranged from 110 to 65 nm. The powder obtained after thermal decomposition is crushed in a planetary mill using zirconia as a grinding tool and a liquid medium in the form of ethanol in the presence of a plasticizer: polyvinyl alcohol in an amount of 4.0 wt. % by weight of powder. Grinding in a planetary mill is carried out for 60 minutes. After grinding, the powder is dried, followed by granulation by spray drying, the temperature in the spray dryer at the inlet is about 90-110 ° C. The resulting powders are formed by isostatic pressing at pressures up to 200 MPa to obtain compacts of a given shape with a relative density of 55%. After cold isostatic pressing, the formed samples are heat treated in an inert gas at a temperature of 800 ° C, with a heating rate of 1 ° C / min, the exposure time is 4 hours. Then the compacts are sintered in a vacuum. The sintering temperature of 1700-1750 ° C, the exposure time is 15 hours, the degree of vacuum is 10 ^-5 Pa. After vacuum sintering, ceramic samples are annealed in air, heated to 1400 ° C with a heating rate of 1 ° C / min, the exposure time is 5 hours, cooled to 600 ° C at a speed of 3 ° C / min, then with a furnace. After sintering in vacuum, ceramic samples are obtained which are subjected to thermal annealing in air at a temperature of 1400 ° C for 5 hours.

Brief description of the attached illustrations

FIG. 1 - Micrograph of a sample (according to example 1) of composition Y _2.76 Er _0.015 Sc _0.6 Al _4.625 O ₁₂ .

Figure 2 - Spectral light transmission curve of ceramics Er: YAG (Sc), erbium content (Er ³⁺ ) 0.5 at. %, scandium (Sc ³⁺ ) 20.0 at. %

FIG. 3 - Luminescence spectrum of a ceramic sample Er: YAG (Sc), erbium content (Er ³⁺ ) 0.5 at. %, scandium (Sc ³⁺ ) 20.0 at. % Here a characteristic series of bands appears in the region of 540–700 nm, the most intense lines, which are the bands at 557 and 680 nm.

FIG. 4 - Micrograph of a sample (according to example 2) of composition Y _2.813 Er _0.015 Sc _0.45 Al _4.719 O ₁₂ .

FIG. 5 - Micrograph of a sample (according to example 3) of the composition Y _2.873 Er _0.015 Sc _0.3 Al _4.813 O ₁₂ .

Table 1 (see the end of the description) presents the main characteristics of scintillators made according to the prototype and the proposed material, the methods for which are illustrated by the following examples (the table shows the data for examples 1 and 3).

Example 1. Prepare an initial solution of yttrium, aluminum, erbium and scandium chlorides of a given composition, based on the composition formula Y _2.76 Er _0.015 Sc _0.6 Al _4.625 O ₁₂ , by dissolving the chlorides in deionized water by heating and evaporated to a concentrated state . The hot concentrated chloride solution is then sprayed into the precipitator solution. The precipitant is prepared as follows. A solution of carbon ammonium salts in 25% concentration at 25 ° C is preliminarily prepared. Then the resulting solution of carbon ammonium salts of 25% concentration is mixed with a 25% solution of ammonium hydroxide in a volume ratio of 1: 1. During precipitation, a 100% excess of precipitant is used with respect to the stoichiometric amount of cations in the chloride solution. Upon contact between a solution of yttrium, aluminum, erbium, and scandium chlorides and a precipitant, a precipitate instantly forms from small spherical particles, which are present as a colloidal suspension of the precipitate in the mother liquor. Next, the precipitate is decanted in deionized water. The decantation process removes excess ammonium hydroxide and ammonium carbonate and reaction products: ammonium chloride from the precipitate. Then the precipitate is separated from the wash solution by filtration. The precipitate is dried at a temperature of about 100 ° C by vacuum drying for 2 hours. Studies of the obtained precursor by the method of nitrogen absorption by the BET method showed that the samples have a specific surface area of 3.741 m2 / g. The dried precipitate is calcined in air at a temperature of 1000 ° C for 2 hours for thermal decomposition and the formation of the crystalline structure of a cubic solid solution with a garnet structure. The specific surface area of the obtained powders with the garnet structure was measured by the nitrogen absorption method by the BET method, and varied from 8 to 20 m2 / g. The sizes of crystallites with a garnet structure, measured using scanning electron microscopy, ranged from 110 to 65 nm. The powder obtained after thermal decomposition is crushed in a planetary mill using zirconia as a grinding tool and a liquid medium in the form of ethanol in the presence of a plasticizer: polyvinyl alcohol in an amount of 4.0 wt. % by weight of powder. Grinding in a planetary mill is carried out for 60 minutes. After grinding, the powders are dried, followed by granulation by spray drying, the temperature in the spray dryer at the inlet is about 90-110 ° C. The resulting powders are formed by isostatic pressing at pressures up to 200 MPa to obtain compacts of a given shape with a relative density of 55%. After cold isostatic pressing, the formed samples are heat treated in an inert gas at a temperature of 800 ° C, with a heating rate of 1 ° C / min, the exposure time is 4 hours. Then the compacts are sintered in a vacuum. The composition of Y _2.76 Er _0.015 Sc _0.6 Al _4.625 O ₁₂ , sintered in vacuum at a temperature of 1700 ° C for 15 hours. The relative density of the ceramic material is> 99.99%. The content of Sc ³⁺ is 20.0 at. %, average grain size of 3.0 microns.

The type and structure of the ceramic sample is shown in FIG. 1. After sintering in vacuum, ceramic samples are obtained which are subjected to thermal annealing in air at a temperature of 1400 ° C for 5 hours.

The main scintillation parameters are presented in Table 1. The optical ceramics obtained from this precursor had the following characteristics: light transmission of 85% (Fig. 2), a characteristic series of bands in the region of 540-700 nm, the most intense lines, appear in the luminescence spectrum (Fig. 3), which are the bands at 557 and 680 nm.

Example 2. An initial solution is prepared from yttrium, aluminum, erbium and scandium chlorides of a given composition, based on the composition formula Y _2.813 Er _0.015 Sc _0.45 Al _4.719 O ₁₂ , by dissolving the chlorides in deionized water by heating and evaporated to a concentrated state. The hot concentrated chloride solution is then sprayed into the precipitator solution. The precipitant is prepared as follows. A solution of carbon ammonium salts in 25% concentration at 25 ° C is preliminarily prepared. Then the resulting solution of carbon ammonium salts of 25% concentration is mixed with a 25% solution of ammonium hydroxide in a volume ratio of 1: 1. During precipitation, a 100% excess of precipitant is used with respect to the stoichiometric amount of cations in the chloride solution. Upon contact between a solution of yttrium, aluminum, erbium, scandium, and precipitant chlorides, a precipitate is formed from small spherical particles, which are present in the form of a colloidal suspension of the precipitate in the mother liquor. Next, the precipitate is decanted in deionized water. The decantation process removes excess ammonium hydroxide and ammonium carbonate and reaction products: ammonium chloride from the precipitate. Then the precipitate is separated from the wash solution by filtration. The precipitate is dried at a temperature of about 100 ° C by vacuum drying for 2 hours. Studies of the obtained precursor by the method of nitrogen absorption by the BET method showed that the samples have a surface equal to 3.741 m2 / g. The dried precipitate is calcined in air at a temperature of 1000 ° C for 2 hours for thermal decomposition and the formation of the crystalline structure of a cubic solid solution with a garnet structure. The specific surface area of the obtained powders with a garnet structure was measured by the nitrogen absorption method by the BET method and varied from 8 to 20 m2 / g. The sizes of crystallites with a garnet structure, measured using scanning electron microscopy, ranged from 110 nm to 65 nm. The powder obtained after thermal decomposition is ground in a planetary mill using zirconia as a grinding tool and a liquid medium in the form of ethanol in the presence of a plasticizer: polyvinyl alcohol, in an amount of 4.0 wt. % by weight of powder. Grinding in a planetary mill is carried out for 60 minutes. After grinding, the powders are dried, followed by granulation by spray drying, the temperature in the spray dryer at the inlet is about 90-110 ° C. The resulting powders are formed by isostatic pressing at pressures up to 200 MPa to obtain compacts of a given shape with a relative density of 55%. After cold isostatic pressing, the formed samples are heat treated in air, in an inert gas at a temperature of 800 ° C, with a heating rate of 1 ° C / min, the exposure time is 4 hours. Then the compacts are sintered in a vacuum. Composition Y _2.813 Er _0.015 Sc _0.45 Al _4.719 O ₁₂ is sintered in vacuo at a temperature of 1700 ° C. for 15 hours. The relative density of the ceramic material is> 99.99%. The content of Sc ³⁺ is 15.0 at. %, average grain size of 4.0 microns.

The type and structure of the ceramic sample is shown in FIG. 4. After sintering in vacuum, ceramic samples are obtained which are subjected to thermal annealing in air at a temperature of 1400 ° C for 5 hours. The optical ceramics obtained from this precursor had a light transmission of 85%.

Example 3. An initial solution is prepared from yttrium, aluminum, erbium and scandium chlorides of a given composition, based on the composition formula Y _2.873 Er _0.015 Sc _0.3 Al _4.813 O ₁₂ , by dissolving the chlorides in deionized water by heating and evaporated to a concentrated state. The hot concentrated chloride solution is then sprayed into the precipitator solution. The precipitant is prepared as follows. A solution of carbon ammonium salts in 25% concentration at 25 ° C is preliminarily prepared. Then the resulting solution of carbon ammonium salts of 25% concentration is mixed with a 25% solution of ammonium hydroxide in a volume ratio of 1: 1. During precipitation, a 100% excess of precipitant is used with respect to the stoichiometric amount of cations in the chloride solution. Upon contact between a solution of yttrium, aluminum, erbium, scandium, and precipitant chlorides, a precipitate is formed from small spherical particles, which are present in the form of a colloidal suspension of the precipitate in the mother liquor. Next, the precipitate is decanted in deionized water. The decantation process removes excess ammonium hydroxide and ammonium carbonate and reaction products: ammonium chloride from the precipitate. Then the precipitate is separated from the wash solution by filtration. The precipitate is dried at a temperature of about 100 ° C by vacuum drying for 2 hours. The study of the obtained precursor by the method of nitrogen absorption by the BET method showed that the samples have a specific surface of 3.741 m2 / g. The dried precipitate is calcined in air at a temperature of 1000 ° C for 2 hours for thermal decomposition and the formation of the crystalline structure of a cubic solid solution with a garnet structure. The specific surface area of the obtained powders with a garnet structure was measured by the nitrogen absorption method by the BET method and varied from 8 to 20 m2 / g. The sizes of crystallites with a garnet structure, measured using scanning electron microscopy, ranged from 110 to 65 nm. The powder obtained after thermal decomposition is crushed in a planetary mill using zirconia as a grinding tool and a liquid medium in the form of ethanol in the presence of a plasticizer: polyvinyl alcohol in an amount of 4.0 wt. % by weight of powder. Grinding on a planetary mill is carried out for 40 minutes.

After grinding, the powders are dried, followed by granulation by spray drying, the temperature in the spray dryer at the inlet is about 90-110 ° C. The resulting powders are formed by isostatic pressing at pressures up to 200 MPa to obtain compacts of a given shape with a relative density of 55%. After cold isostatic pressing, the formed samples are heat treated in an inert gas at a temperature of 800 ° C, with a heating rate of 1 ° C / min, the exposure time is 4 hours. Then the compacts are sintered in a vacuum. Composition Y _2.873 Er _0.015 Sc _0.3 Al _4.813 O ₁₂ is sintered in vacuo at a temperature of 1750 ° C. for 15 hours. The relative density of the ceramic material is> 99.99%. The content of Sc ³⁺ - 10.0 at. %, average grain size of 4.5 microns. The type and structure of the ceramic sample is shown in FIG. 5.

After sintering in vacuum, ceramic samples are obtained which are subjected to thermal annealing in air at a temperature of 1400 ° C for 5 hours.

The main scintillation parameters are presented in Table 1. The optical ceramics obtained from this precursor had a transmittance of 85%.

Thus, the claimed method for producing transparent polycrystalline solid-state scintillation materials, as well as the creation of scintillation structures in which the main matrix of the material is yttrium - aluminum garnet of controlled composition, including partial substitution of cations in the main YAG composition, allows to obtain a transparent ceramic scintillation material based on yttrium - aluminum garnet doped with Er ³⁺ ions - 0.5 at. % and Sc ³⁺ ions - 10.0 - 20.0 at. %, with a transmittance in the visible region of the spectrum of 85% and the main scintillation parameters: the emission region of 540-700 nm with two maxima of 557 nm and 680 nm; light output 56-74% relative to CsI (Tl); the duration of the scintillation pulse is 53-44 ns.

Claims (4)

1. A method for producing a transparent polycrystalline solid-state scintillation material with a garnet structure doped with rare-earth ions, including dissolving the initial cations of salts, evaporating to a concentrated state, co-precipitating through sputtering, followed by filtering the precursor precipitate, decanting, drying and heat treatment, compaction and compaction and characterized in that yttrium-aluminum garnet is used as a material with a garnet structure ionized with Er ³⁺ and Sc ³⁺ ions, to prepare which an initial solution of the desired cations of a given composition is prepared by dissolving yttrium, aluminum, erbium and scandium chlorides in deionized water by heating and evaporated to a concentrated state and sprayed into a previously prepared precipitator, the precipitate obtained is decanted in deionized water, then the precipitate is dried at a temperature of 90-110 ° C by vacuum drying for 2 hours and calcined in air at a temperature of 1000 ° C for 2 hours to obtain a solid powder solution with the structure of a garnet, then the powder is ground in a planetary mill using zirconia as a grinding tool in ethanol in the presence of polyvinyl alcohol in an amount of 4.0 wt. % by weight of the powder, followed by drying and obtaining granules, after granulation, the powder is formed by isostatic pressing at a pressure of up to 200 MPa to obtain compacts with a relative density of 55%, then the compacts are heat-treated in an inert gas at 800 ° C for 4 hours, followed by vacuum sintering at a temperature of 1700-1750 ° C for 15 hours; after vacuum sintering, ceramic samples are obtained which are subjected to thermal annealing in air at a temperature of 1400 ° C for 5 hours. 2. The method according to p. 1, characterized in that as a precipitant use a mixture of an aqueous solution of carbon ammonium salts of 25% concentration and a solution of ammonium hydroxide 25% in a volume ratio of 1: 1. 3. The method according to p. 1, characterized in that as an activating additive is used scandium in an amount of 10-20 at. % 4. The method according to p. 1, characterized in that the concentration of Er ³⁺ cations in the scintillation material of polycrystalline yttrium aluminum garnet is 0.015 mol. % in terms of erbium oxide.

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