RU2806531C1 - Luminescent method for determination of uncontrolled impurities and heterogeneity of their surface distribution - Google Patents

Abstract

FIELD: measurements.

SUBSTANCE: invention relates to photoluminescent analysis methods for determining the content of uncontrolled impurities and monitoring their surface distribution in oxide materials. A method for determining uncontrolled impurities and the heterogeneity of their surface distribution includes the addition of europium oxide in an amount of no more than 0.1 mol.%. into the composition of an oxide material sample during the synthesis process, registration of luminescence spectra upon excitation by laser radiation from various parts of the sample during confocal scanning of a selected area, analysis of the relative intensity of luminescence lines of impurity ions and europium ions in different areas of the surface of the material in accordance with surface images obtained by the confocal method microscopy.

EFFECT: control of the surface distribution of uncontrolled impurities in oxide materials.

1 cl, 5 dwg

Description

The invention relates to methods of photoluminescent analysis, and can be used to determine the content of uncontrolled impurities and control their surface distribution in oxide materials.

An extremely important requirement for the effective practical use of materials is their chemical purity. This is due to the fact that the presence of even a small amount of impurities can significantly change their structural and physicochemical properties. Certain impurities may be acceptable, but their quantity and distribution must be strictly controlled to ensure stability of material properties. The sources of impurities entering the material can be both contamination of the raw materials used for synthesis, including binders and equipment materials, and the atmosphere in which the production process takes place. Therefore, control of impurities must be carried out at all stages of the material's production to ensure maximum performance and reliability in high-tech industrial applications.

To analyze oxide materials, various physical and chemical methods are used, depending on the range of controlled impurities, the type and degree of purity of each specific substance.

There are known methods for determining microimpurities in oxide materials using X-ray fluorescence spectroscopy (D'Sliva A.P., Fassel V.A. X-ray excited optical fluorescence of trace rare earths in yttrium phosphate and yttrium vanadate hosts. Part per giga level determination of rare earth impurities in yttrium oxide. Analytical Chemistry. - 1973. - V. 45. - P. 542-547), atomic emission spectrometry with inductively coupled plasma and mass spectrometry with inductively coupled plasma (Zhernokleeva K.V., Baranovskaya V.B. Analysis pure scandium, yttrium and their oxides by methods of atomic emission spectrometry with inductively coupled plasma and mass spectrometry with inductively coupled plasma // Factory Laboratory. Diagnostics of Materials. - 2010. - T. 76. - No. 11. - P. 20- 26).

A significant disadvantage of these methods is the destructive nature of the effect on the structure of the material and the need for preliminary sample preparation of the sample.

Non-destructive methods for monitoring the impurity composition include luminescent methods. Their use for the analysis of microimpurities in oxide materials is described in a number of works (Cui J., Hope GA Raman and Fluorescence Spectroscopy of CeO ₂ , Er ₂ O ₃ , Nd ₂ O ₃ , Tm ₂ O ₃ , Yb ₂ O ₃ , La ₂ O ₃ , and Tb ₄ O _7. Journal of Spectroscopy. - 2015. - V. 2015. - P. 940172; P. Fornasiero, A. Speghini, R. Di Monte, M. Bettinelli, J. Kaspar, A. Bigotto, V. Sergo, M. Graziani, Laser-Excited Luminescence of Trivalent Lanthanide Impurities and Local Structure in CeO ₂ -ZrO ₂ Mixed Oxides, Chem. Mater. - 2004. - V. 16. - P. 1938-1944).

There is a known luminescent method for determining the concentration of luminescence centers in oxygen-containing materials. The invention relates to methods for determining the concentration of impurity and intrinsic defects in oxygen-containing materials, namely to a luminescent method for determining the concentration of luminescence centers, and can be used for technological control of substances and in ecology for monitoring ice and water. The method includes excitation of luminescent impurities and intrinsic defects by an electron beam, the duration of which is 0.1 of the radiative lifetime of the shortest-lived luminescence center, registration of luminescence, identification of characteristic bands in the luminescence spectrum, identification of luminescence centers, measurement of the intensities of the standard and characteristic bands, determination of concentration using data on calibration samples. The internal standard of sensitivity is chosen to be the own fundamental broadband glow of the material under study, the duration of which is less than the emission time of the glow centers (RU 2110059, IPC G01N 21/62, publ. 04/27/1998).

The disadvantage of this method is the impossibility of determining the heterogeneity of the distribution of impurities over the surface of the material.

The closest in essence to the proposed method is the luminescent method for determining the concentration of impurities in crystalline materials (RU 2667678, IPC G01N 21/62, G01J 1/58, publ. 09.24.2018). The method includes excitation of luminescent impurities with a femtosecond laser pulse, registration of luminescence, identification of characteristic bands in the luminescence spectrum, identification of luminescence centers, measurement of standard intensities and characteristic bands, determination of concentration using data from calibration samples, where the sensitivity standard is the own fundamental broadband luminescence of the material under study, the duration of which is less than the emission time of the impurity luminescence center.

A significant disadvantage of this method is the impossibility of determining the heterogeneity of the distribution of impurities over the surface of the material.

The technical result of the invention is to provide control of the surface distribution of uncontrolled impurities in oxide materials through the combined use of photoluminescence spectroscopy methods using europium ions as a spectroscopic probe and confocal microscopy.

The essence of the luminescent method for determining uncontrolled impurities and the heterogeneity of their surface distribution is that it includes the addition of europium oxide in an amount of no more than 0.1 mol.%. into the composition of an oxide material sample during the synthesis process, registration of luminescence spectra upon excitation by laser radiation from various parts of the sample during confocal scanning of a selected area, analysis of the relative intensity of luminescence lines of impurity ions and europium ions in different areas of the surface of the material in accordance with surface images obtained by the confocal method microscopy.

The method is carried out as follows.

The method for determining uncontrolled impurities and the heterogeneity of their surface distribution can be carried out both at all stages of the technology for producing oxide material, and on finished products made of oxide materials.

During the synthesis process, europium oxide is added to the composition of the analyzed oxide material in an amount of no more than 0.1 mol. % of the total number of components of the oxide material. To determine the content of uncontrolled impurities in a sample, luminescence spectra are recorded using a spectrophotometer when excited by laser radiation.

To control the distribution of the identified uncontrolled impurity in the sample, images of a selected surface area are obtained using a confocal microscope, luminescence spectra are recorded when excited by laser radiation in various parts of this area, and they are analyzed.

The uneven surface distribution of an uncontrolled impurity in the samples under study will be indicated by a change in the relative intensity of the lines of impurity ions and europium ions depending on the surface area, as well as the obtained maps of the intensity distribution of luminescence lines of impurity ions on a selected area of the sample surface.

Example 1

To diagnose the impurity composition, ceramic samples of solid solutions (ZrO ₂ ) _0.909 (Y ₂ O ₃ ) _0.09 (Eu ₂ O ₃ ) _0.001 were selected. As a starting material for the manufacture of ceramics, we used powder obtained by grinding single crystals of a similar composition, the synthesis of which was carried out by the method of directional crystallization of the melt [VI Aleksandrov, VV Osiko, AM Prokhorov, VM Tatarintsev. Synthesis and crystal growth of refractory materials by RF melting in a cold container // Curr. Top. Mater. Sci., Amsterdam. - 1978. - V. 1. - P. 421-480]. To prepare the initial charge, oxides of zirconium (ZrO ₂ ), yttrium (Y ₂ O ₃ ) and europium (Eu ₂ O ₃ ) were used with a basic oxide content of at least 99.96 wt. %.

Ceramics samples were obtained using uniaxial pressing technology from pre-crushed powder. Grinding was carried out with the addition of oleic acid in a drum lined with plates and grinding media made of zirconium dioxide stabilized with yttria. The resulting powder was pressed into disks (radius ~ 15 mm, thickness ~ 0.48 mm) at a pressure of 15 kN. Heat treatment of the samples was carried out in air at 1680°C with exposure for 2 hours in furnaces with heaters made of lanthanum chromite (LaСrO ₃ ) in closed crucibles made of corundum ceramics VK-97 (Al ₂ O ₃ -97%; SiO ₂ -3%).

To determine the content of uncontrolled impurities in the ceramic material (ZrO ₂ ) _0.909 (Y ₂ O ₃ ) _0.09 (Eu ₂ O ₃ ) _0.001 , luminescence spectra were recorded in the region of 400-800 nm when excited by radiation with a wavelength of 532 nm using an FHR spectrophotometer 1000 produced by Horiba. To prove the reliability of the method, luminescence spectra of single crystals of similar composition were also recorded. The recorded luminescence spectra of these ceramics and crystals are presented in Fig. 1. The luminescence spectra of the crystals contained only lines characteristic of the ⁵ D ₀ → ⁷ F _0-4 transitions of Eu ³⁺ ions (Fig. 1, curve 1), which indicates the absence of uncontrolled impurities in the original single crystals. In the spectra of the ceramics, in addition to the luminescence lines of Eu ³⁺ ions, there are two more intense narrow lines in the region of 693 and 694.5 nm (Fig. 1, curve 2). Taking into account the results of [A. Kostyukov, M. Baronskiy, A. Rastorguev, V. Snytnikov, V. Snytnikov, A. Zhuzhgov, A. Ishchenko. Photoluminescence of Cr ³⁺ in nanostructured Al ₂ O ₃ synthesized by evaporation using a continuous wave CO ₂ laser // RSC Adv. - 2016. - V. 6. - P. 2072-2078] we can conclude that these changes in the luminescence spectra of ceramics are caused by optical transitions ² E → ⁴ A _{2 of} Cr ³⁺ ions (the so-called R-lines) in Al ₂ O ₃ . This fact determines the content of Cr ₂ O ₃ -Al ₂ O ₃ impurity in the ceramics under study, the occurrence of which is associated with the technological conditions of the synthesis of this material.

To control the distribution of identified uncontrolled impurities Cr₂O₃-Al₂O₃ in ceramics (ZrO₂)_0.909(Y₂O₃)_0.09(Eu₂O₃)_0.001 Images of a selected surface area (50 × 50 μm) were obtained using a confocal microscope (Fig. 2) and luminescence spectra were recorded in the region of 560-750 nm when excited by radiation with λ = 473 nm in various parts of this area (Fig. 3). In fig. Figure 4 shows these luminescence spectra in the region of 690-700 nm. The studies were carried out using the NTEGRA SPECTRA installation manufactured by NT-MDT. The analysis of the results was carried out using the obtained maps of the intensity distribution of luminescence lines R₁ and R₂ Cr ions³⁺ to Al₂O₃ on a selected area of the sample surface (Fig. 5), where the light areas corresponded to the highest line intensity and the presence of a large number of impurities. Map data was generated using Nova software. Spectra in Fig. 3 are presented in relative units of measurement, reduced to unity relative to the luminescence line with a maximum of 606.4 nm, due to⁵D₀ →⁷F₂ transition Eu ions³⁺. The color of the curve lines corresponds to the color on the intensity distribution map. Accordingly, analysis of intensity distribution maps of luminescence lines R₁ and R₂ Cr ions³⁺ to Al₂O₃ depending on the surface area of the ceramics, revealed that the uncontrolled admixture of Cr₂O₃-Al₂O₃ in the studied samples is distributed unevenly.

Compared to the known solution, the claimed invention makes it possible to analyze the distribution of uncontrolled impurities over the surface of the material.

The invention was created at the expense of the Fund for Assistance to the Development of Small Enterprises in the Scientific and Technical Field (agreement No. 16318GU/2021 dated 05.20.2021).

Claims (1)

A method for determining uncontrolled impurities and the heterogeneity of their surface distribution in oxide materials, including the addition of europium oxide in an amount of no more than 0.1 mol.%. into the composition of an oxide material sample during the synthesis process, registration of luminescence spectra upon excitation by laser radiation from various parts of the sample during confocal scanning of a selected area, analysis of the relative intensity of luminescence lines of impurity ions and europium ions in different areas of the surface of the material in accordance with surface images obtained by the confocal method microscopy.