RU2750694C1 - Method for production of an inorganic temperature indicator - Google Patents

Abstract

FIELD: inorganic chemistry.

SUBSTANCE: invention relates to the field of inorganic chemistry and can be used in production of an irreversible luminescent temperature indicator. First, cerium dioxide and terbium(III, IV) oxide are dissolved in concentrated orthophosphoric acid. The molar ratio of Ce:Tb therein is 20:1 to 5:1, and the concentration of cerium in the cerium phosphate solution is 0.01 to 0.8 M. Distilled water is added to the resulting cerium phosphate solution so that the volumetric ratio of cerium phosphate solution : distilled water is from 1:3 to 1:8. The formed gel is purified from excess phosphoric acid, dried, and a xerogel of amorphous cerium (IV) orthophosphate containing terbium is obtained, e.g., in form of a thin-layered material. After annealing at temperatures of approximately 700°C, the resulting product exhibits green luminescence under UV irradiation and can be used as a temperature indicator both by itself and in compositions comprising other components.

EFFECT: invention allows to expand the range of technical means intended for visual registration of the overheating temperature of parts or equipment at high temperatures.

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Description

The invention relates to the field of inorganic chemistry, namely to a method for producing an irreversible temperature indicator based on amorphous cerium (IV) orthophosphate, and can be used for visual monitoring of overheating of parts or equipment in various technological processes.

Thermal indicators are one of the most popular means of recording temperature. Thermal indicators primarily include thermochemical compositions that change their color at the transition temperature, materials that melt at a certain temperature and phosphors, the brightness or color of the glow of which depends on the temperature [A.P. Leonov, V.A. Bolgov. Bulletin of Eurasian Science, 2014, p. 1-8]. Thermal indicators are intended for both single use, if the process of changing external parameters is irreversible, and reusable. The areas of application of thermal indicators are extremely diverse: ensuring safety at work and in everyday life, industrial monitoring of the temperature regimes of equipment operation; overheating verification during the warranty period; checking the temperature of aircraft systems, measuring the temperature of equipment parts with difficult access, etc. Due to the wide range of applications, indicators with a different operating range of measured critical temperatures, up to 1500 ° C [E.A. Kolenko. Laboratory experiment technology: Handbook. SPb .: Polytechnic, 1994, 69]. For example, known thermochromic indicator of overheating of the barrel of a weapon [US 10352641], capable of heating up to 430 ° C at a high rate of fire. Known powder thermal indicator [RU 2343434], designed to determine the heating temperature of metals and alloys exposed to general or local heating, igniting at 350 ° C. However, most thermal indicators, including luminescent ones, contain an organic component and operate at temperatures not exceeding 200 ° C [RU 2290648, RU 2443707, RU 2551373, RU 782366]. For areas of production where indicators of high overheating temperatures are required, it is advisable to use completely inorganic compositions. Luminophores based on phosphates of rare earth elements (REE) are promising compounds for this. The temperature at which the luminescent properties appear or disappear can be used as a thermal indicator signal based on them.

Known phosphor based on mixed phosphate of lanthanum-cerium-terbium composition La _x Ce _y Tb _1-xy PO ₄ , where x is in the range from 0.4 to 0.6, and x + y is greater than 0.8, exhibiting luminescent properties above 500 ° C [US 5562889 ]. As one of the examples of implementation of the invention, a method for producing a phosphor is indicated, including mixing solutions of trivalent REE nitrates with an ammonium phosphate solution heated to 80 ° C. The mixture was stirred for 4 h at pH = 2, then the precipitate was washed and annealed at 700 ° C for 8 h.

The disadvantage of this method is the duration of the processes of mixing the suspension and annealing.

A similar method is presented in patent FR2931143. In particular, to obtain a luminescent mixed lanthanum-cerium-terbium phosphate of the composition La _0.56 Ce _0.3 Tb _0.14 PO ₄ , a solution of a mixture of lanthanum, cerium, and terbium nitrates is prepared and added to a phosphoric acid solution at 60 ° C at pH = 1.6. After precipitation, the reaction medium is kept for 15 minutes at 60 ° C. Then the precipitate is washed with water, dried in air and calcined at 850 ° C.

A known method of obtaining [US 8419974] luminescent nanocrystalline rare earth phosphate, including mixing in an aqueous medium of a source of phosphate anions, at least one water-soluble salt of REE (La, Lu, Gd) and at least one water-soluble salt of the activating element (Pr, Nd, Eu, Ce, Tb, Bi or Pb) with subsequent annealing of the deposit at temperatures of 300-400 ° C for 1-10 h.

The disadvantage of the proposed method is the relatively low temperature of the appearance of luminescent properties.

A common disadvantage of the above methods for producing phosphors is the use of three or more rare earth elements, which increases the cost of the production technology.

It is known that cerium (III) orthophosphate with a monazite structure, doped with various cations (for example, terbium or manganese, europium, etc.), has luminescent properties [S. Lv, W. Di, Z. Liu, et al. Analyst, 2014, 139 (18), 4547-4555; Y. Ding, L.-B. Liang, M. Li et al. Nanoscale Res. Lett., 2011, 6 (1), 119; G. Li, K. Chao, H. Peng, et al. J. Phys. Chem. C., 2008, 112 (42), 16452-16456]. In a number of works, doped CePO _{4 is} proposed to be used as an indicator, where the emergence or, conversely, disappearance of luminescent properties will serve as an analytical signal. This phenomenon is based on the reversible transition Ce (III) / Ce (IV), depending on the surrounding atmosphere - whether it is oxidizing or reducing. In particular, the oxidation of Ce (III) to Ce (IV) serves as the main factor for quenching the emission of Tb in CePO ₄ : Tb, and the reduction of Ce (IV) to Ce (III) leads to the return of the luminescent properties [W. Di, X. Wang, X. Ren. Nanotechnology, 2010, 21 (7), 075709; Q. Li and VWW Yam. Angew. Chemie - Int. Ed., 2007, 46 (19), 3486-3489]. However, this effect is based on the action of the atmosphere, not temperature. At the same time, when exposed to temperature, an irreversible Ce (IV) - Ce (III) transition is possible, which occurs, for example, during the annealing of acidic cerium (IV) orthophosphates at temperatures of about 700 ° C [V. Brandel, N. Clavier, and N. Dacheux. J. Solid State Chem., 2005, 178 (4), 1054-1063]

A known method of producing an amorphous xerogel based on acidic cerium (IV) orthophosphate [T.O. Shekunova, A.E. Baranchikov, O.S. Ivanova, et al. J. Non-Cryst. Solids, 2016, 447, 183-189]. First, cerium dioxide is dissolved in concentrated orthophosphoric acid at 100 ° C and a cerium phosphate solution is obtained with [Ce] = 0.1 M. After cooling, distilled water is added to it in a volume ratio of "cerium phosphate solution": "distilled water" = 1: 7. The formed gel is washed to remove excess phosphoric acid and dried. When the product is annealed at about 700 ° C, a partial reduction of Ce (IV) to Ce (III) occurs, accompanied by the formation of monazite.

The resulting cerium phosphate xerogel at the transition temperature Ce (IV) - Ce (III) lacks luminescent properties, since the method does not provide for the doping stage.

A known method of producing an inorganic temperature indicator [JP 2006329666], taken as a prototype. The invention claims a material containing an inorganic pigment with an inorganic binder, which changes color from white to yellow when the temperature rises. It is proposed to use titanium oxide (rutile) and / or cerium oxide as an inorganic pigment, and glass fiber as an inorganic binder. In a particular example of the implementation of the method, it is indicated that titanium oxide is mixed with glass fiber and annealed at 800 ° C in order to obtain an inorganic thermochromic composite.

As a disadvantage of the prototype, it should be noted the need to use high annealing temperatures at the stage of preparing the indicator. Also, as a disadvantage, it can be noted that, despite the high thermal stability, the resulting material predominantly changes color in the temperature range up to 300 ° C.

The invention is aimed at expanding the number of possible technical means intended for visual registration of temperature.

The technical objective of the invention is to develop a method for producing an inorganic indicator, with the help of which it is possible to visually detect areas of overheating of parts or equipment at high temperatures.

The technical result is achieved in that a method for producing an inorganic temperature indicator is proposed, characterized in that cerium dioxide and terbium (III, IV) oxide are dissolved in concentrated orthophosphoric acid, distilled water is added to the resulting cerium phosphate solution, the formed gel is purified from excess phosphoric acid, dried and a xerogel is obtained, while the concentration of cerium in the cerium phosphate solution is 0.01-0.8 M, the volume ratio "cerium phosphate solution": "distilled water" varies from 1: 3 to 1: 8, the molar ratio of Ce: Tb = 20: 1-5: one.

It is advisable that the xerogel can be obtained in the form of a thin-layer material.

The concentration range of the cerium phosphate solution was chosen from the considerations that at a concentration of less than 0.01 M, no gel is formed, and a concentration of more than 0.8 M is the maximum possible concentration of a cerium phosphate solution.

The volumetric ratio "cerium phosphate solution": "distilled water" varies from 1: 3 to 1: 8, since a gel is formed within these limits at the indicated concentrations of the cerium phosphate solution.

The range of molar ratios Ce: Tb = 20: 1-5: 1 was chosen on the basis that with a lower terbium content, the product after annealing has a weak luminescence, and the use of large amounts of terbium is impractical, since this does not affect the technical result.

If necessary, the xerogel can be dried not only in the form of a powder, but also obtained in the form of a thin-layer material due to the fibrous microstructure of acidic cerium (IV) orthophosphate, which provides the material with mechanical strength.

The essence of the invention lies in the fact that the obtained amorphous xerogel based on acidic cerium (IV) orthophosphate doped with terbium, when annealed in air at about 700 ° C, begins to exhibit luminescent properties - it glows green under the influence of UV irradiation - due to the partial reduction of Ce (IV ) to Ce (III).

The invention is illustrated by the following figures.

FIG. 1. The results of thermogravimetric and differential thermal analysis of the cerium phosphate xerogel obtained a) according to the prototype, b) according to example 1.

FIG. 2. Diffraction pattern of a cerium phosphate xerogel containing terbium a) before annealing, b) after annealing at 700 ° C, all the main peaks refer to cerium pyrophosphate CeP ₂ O ₇ (PDF-2, No. 00-016-0584). The asterisk marks the peaks related to the monazite CePO ₄ (PDF-2, no. 00-032-0199).

FIG. 3. Appearance of a cerium phosphate xerogel with terbium obtained in the form of a thin-layer material according to example 2 a) before annealing, b) after annealing at 700 ° C under the action of UV irradiation (λ = 254 nm).

FIG. 4. Scanning electron microscopy data for a cerium phosphate xerogel with terbium obtained according to example 2 a) before annealing, b) after annealing at 700 ° C.

Below are examples illustrating but not limiting the proposed method.

Example 1.

Nanocrystalline cerium dioxide was dissolved together with Tb ₄ O ₇ (the Ce: Tb molar ratio was 10: 1) in concentrated orthophosphoric acid at 100 ° C. The concentration of cerium in the cerium phosphate solution was 0.1 M. Distilled water was added to the resulting solution in a volume ratio of 1: 7. The resulting gel was purified by dialysis from excess phosphoric acid and dried at 50 ° C for a day. The results of thermogravimetric and differential thermal analysis for the obtained xerogel coincide with the results for the xerogel synthesized according to the prototype, which is shown in FIG. 1. The diffractogram of the product is shown in FIG. 2a. After annealing at 700 ° C for 15 minutes, it luminesced with green light under UV irradiation with a wavelength of λ = 254 nm, according to X-ray phase analysis, trivalent cerium was present in the annealing product in the form of CePO _4, which is shown in Fig. 2b.

Example 2.

According to example 1, characterized in that the gel was washed on a Schott filter and dried under a press. The gel dried as a thin layer material as shown in FIG. 3a. After annealing at 700 ° C for 15 minutes, the product was luminescent with green light under UV irradiation at λ = 254 nm, as shown in FIG. 3b. As a result of annealing, the material was slightly deformed, but not destroyed. The mechanical strength is related to the stability of the fibrous microstructure of the xerogel, which is confirmed by the data of scanning electron microscopy presented in Fig. four.

Example 3.

According to example 1, characterized in that the volumetric ratio of "cerium phosphate solution": "distilled water" was equal to 1: 3. The resulting product exhibited luminescent properties at an annealing temperature above 700 ° C.

Example 4.

According to example 1, characterized in that the volume ratio "cerium phosphate solution": "distilled water" was equal to 1: 8. The resulting product exhibited luminescent properties at an annealing temperature above 700 ° C.

Example 5.

According to example 1, characterized in that the concentration of the cerium phosphate solution was 0.01 M. The resulting product exhibited luminescent properties at an annealing temperature above 700 ° C.

Example 6.

According to example 1, characterized in that the concentration of the cerium phosphate solution was 0.8 M. The resulting product exhibited luminescent properties at an annealing temperature above 700 ° C.

Example 7.

According to example 1, characterized in that the molar ratio of Ce: Tb was 20: 1. The resulting product exhibited luminescent properties at an annealing temperature above 700 ° C.

Example 8.

According to example 1, characterized in that the molar ratio of Ce: Tb was 5: 1. The resulting product exhibited luminescent properties at an annealing temperature above 700 ° C.

The proposed method makes it possible to obtain a thermal indicator based on amorphous cerium (IV) orthophosphate containing terbium, which, after heating to temperatures above 700 ° C, acquires the properties of a phosphor characterized by green luminescence under UV irradiation, and can be used both by itself and in as part of more complex objects for visual control of overheating areas.

Claims (2)

1. A method of producing an inorganic temperature indicator, characterized in that cerium dioxide and terbium (III, IV) oxide are dissolved in concentrated orthophosphoric acid, distilled water is added to the resulting cerium phosphate solution, the formed gel is purified from excess phosphoric acid, dried and a xerogel is obtained, when the concentration of cerium in the cerium phosphate solution is 0.01-0.8 M, the volume ratio of the cerium phosphate solution: distilled water varies from 1: 3 to 1: 8, the molar ratio of Ce: Tb = 20: 1-5: 1. 2. The method according to claim 1, characterized in that the xerogel is obtained in the form of a thin-layer material.

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