RU2383495C2 - Method of producing complex metal oxides - Google Patents

Abstract

FIELD: chemistry. ^ SUBSTANCE: aqueous salt solution which is easily thermally decomposable is mixed with a water-soluble non-ionic polymer such as polyvinyl alcohol with molecular mass ranging from 15000 to 100000 or polyvinyl pyrrolidone with molecular mass ranging from 25000 to 360000. The obtained polymer-salt solution is deposited onto a substrate and dried. The formed film is separated from the substrate and burnt with flame initiation. The size of particles of the obtained complex oxide depends on molecular mass of the initial polymer. The invention enables production of La0.7Sr0.3MnO3 crystals with particle size from 40 to 70 nm and YBa2Cu3O7- crystals with particle size from 0.5 to 10 mcm. ^ EFFECT: high output of end product. ^ 1 dwg, 3 tbl, 3 ex

Description

The present invention relates to the field of production of powders of oxides and complex metal oxides and can be used in the chemical industry for the production of electronic materials, blanks for the manufacture of fuel cells and other current sources, the synthesis of catalysts, modifying additives to building materials, etc.

A known method of producing highly dispersed lithium metal oxides (see, for example, RF patent No. 2240974, publication date 11/27/2004), in particular lithium manganese oxide Li _x Mn ₂ O ₄ , lithium-nickel oxide Li _x NiO ₂ , lithium cobalt oxide Li _x CoO ₂ used mainly for the manufacture of cathode masses in cells of lithium-ion batteries. A method of producing lithium-metal oxides using lithium compounds and metal compounds in the form of mixed aqueous solutions of metal nitrates and lithium supplied to a high-temperature coolant stream followed by separation of a dispersed product from a steam-gas mixture, consists of introducing carbohydrate into the initial solution inert gases are used in the high-temperature coolant, and the dispersed product isolated from the steam-gas-gas stream is subjected to additional heat treatment in an oxidizing atmosphere D at a temperature not exceeding the temperature decay-phase structure lithium metal oxide. Since traditional methods for producing lithiated cobalt, nickel, and manganese oxides are rather complicated and laborious, the use of the proposed method makes it easier to obtain homogeneous finely dispersed powders of lithium metal oxides of the desired crystal structure.

A known method and apparatus for producing nanosized particles (see, for example, patent WO / 2005/037709, publication date April 28, 2005) during the pyrolysis of dispersed liquid-phase materials (precursors), i.e. during the so-called spray pyrolysis. The installation includes containers with initial precursors, a precursors mixer with an ultrasonic device for spraying them into a gas stream, a thermal reactor, and a subsequent dust collector. In the future, a number of products can be obtained from such powdered materials: semiconductors, catalysts, etc.

A known method of producing nanoporous ultrafine powders from alpha alumina (see, for example, application for the grant of a patent of the Russian Federation No. 2005130530, publication date of the application March 10, 2006; international publication number WO 2004/089828, publication date October 21, 2004), in which an inorganic sol is used containing at least one alumina precursor (precursor) and a plurality of alpha alumina seed particles. At least one water soluble organic polymer is added to the sol. Next, freeze-drying of an organic - inorganic sol is carried out to obtain a solid gel and firing a solid gel at a temperature that allows the organic polymer to burn out and cause the formation of a nanoporous powder from alpha alumina containing interconnected primary particles of alpha alumina.

A known method of producing complex oxyfluorides (see RF patent No. 2055038, publication date 02/27/1996), in which a mixture of the starting components is prepared in the form of an aqueous solution containing 0.1-10 wt.% Salts of metal components, 1-50 wt. % water-soluble polymer and ammonium fluoride. The powder is prepared as follows. The solution was poured into plastic cuvettes and dried using an infrared lamp at 60 ° C until a film was formed, which was separated and burned at 890 ° C for 4 hours.

Closest to the present invention is patent EP 1777205 (publication date 04.25.2007), the claims of which in the main paragraph provides a method for producing a complex oxide of perovskite type, comprising the step of dissolving the rare earth nitrate, alkali metal nitrate, magnesium nitrate and organic polymer in a solvent with the formation of the solution, the stage of active mixing of the solution, the stage of preparation of the precursor from the resulting solution by heating and drying, the stage of firing the precursor powder in the atmosphere.

A common drawback of the above analogues and prototype is the lack of a targeted and predictable effect that can control the particle size of the resulting powders.

Common to the above technical solutions is the production of production solutions and their processing, including the initial removal of water (drying) and the subsequent thermal effect on the resulting precursor.

The objective of the present invention is to create a more advanced method of producing oxides and complex metal oxides.

The technical result of the present invention is to control the particle size or crystallite of the resulting powdery products.

To achieve the specified technical result in the method for producing complex metal oxides in powder form, which includes obtaining an aqueous solution, which includes a nonionic water-soluble polymer and salts containing metal ions, removing water from the resulting solution and the subsequent thermal effect on the obtained composite oxide precursor, use salts that readily decompose thermally; polyvinyl alcohol is used as a nonionic water-soluble polymer with a variable molecular weight or polyvinylpyrrolidone, the resulting aqueous solution is applied first to an inert substrate, dried to remove water from the resultant precursor is separated form a film on the substrate is carried out thermal effect on the resulting precursor of the composite oxide through films combustion initiation of ignition and for increasing the size of YBa ₂ Cu ₃ crystallite O _7-δ from 2.8 to 10 μm, polyvinyl alcohol with a molecular weight of from 15,000 to 100,000, respectively, is used; to increase the size of La _0.7 Sr _0.3 MnO ₃ crystallites from 40-50 to 60-70 nm, I use polyvinyl alcohol with a molecular weight of 15,000 and 50,000, respectively, to obtain crystals of YBa ₂ Cu ₃ O _{7-δ with a} size of 7.2 μm and 0.5 μm, polyvinylpyrrolidone is taken with a molecular weight of 25,000 and 360,000, respectively.

The essence of the present invention is as follows.

Currently, polymers are widely used in the technology of complex oxides (see, for example: 1) RF patent No. 2048617, publication date 11/20/1995; 2) RF patent No. 2048618, date of publication of November 20, 1995; 3) WO 2002/094711, publication date 11/28/2002; 4) WO 2006/022255, date of publication 02.03.2006; 5) WO 2006/001154, publication date January 5, 2006, etc.).

In our studies, ready-made non-ionic water-soluble polymers of industrial production were selected as the polymer constituent parts of the compositions used for the synthesis of oxide materials: primarily polyvinyl alcohol, as well as polyvinylpyrrolidone, methyl cellulose (MC), polyacrylamide, polyethylene glycol and polyethylene oxide. These high molecular weight substances make it possible to fairly easily and quickly obtain the initial polymer-salt solutions with various salts in a wide range of pH, concentrations of polymer and salt components, without forming precipitation.

It is advisable to choose salts that readily decompose thermally as the starting salts containing metal ions for the synthesis of complex oxides. These include organic salts (acetates, formates, citrates, tartrates, etc.); Among inorganic salts, nitrates are most suitable, although some sulfates and even halides are possible.

Upon receipt of complex oxide powders, the content of salts of metal components in solutions is usually taken 0.1-10 wt.%. The concentration of the polymer part is usually 1-50 wt.%. When choosing the desired concentrations, it is advisable to be guided by the literature data on the solubility diagrams of polymers in water and information on the solubility of salts, including triple systems of practical importance. Commonly used nitrates, formates, acetates satisfy the requirements for the stability of solutions.

Complex oxide powders themselves can be obtained mainly in two ways. The above method is described in which the dispersion of the polymer-salt solution is carried out in a heated thermochemical reactor. When spraying solutions containing the polymer into a heated thermochemical reactor, first of all, water is removed from the drop and then an exothermic redox reaction occurs. Typically, pyrolysis begins at temperatures of 120-160 ° C. The temperature developing during pyrolysis can reach 600-1000 ° C or more.

A suitable method for producing complex oxides in powder form, in which the preparation of a polymer-salt solution is also carried out. For this, salt solutions are usually prepared separately with a given stoichiometry of metal components (the content of the latter is in the range of 0.1-10 wt.%) And aqueous polymer solutions with concentrations of about 1-50 wt.%. Next, the polymer and salt parts are mixed in the desired proportions. The main process includes the pouring of working solutions on the surface of indifferent carriers and the removal of water from solutions (drying of the latter) to obtain a precursor in the form of a film. The resulting film is then either left on the substrate, or is separated from it and burned at the initial initiation of ignition.

Ignition can be initiated, for example, by applying to the film a small amount (several drops) of a combustible liquid that does not give inorganic impurities in the resulting complex oxide (alcohol, acetone, etc.), and further exposure to an open flame. The burning process of the film is especially stable in those cases when the ions of the metals that make up the complex oxide can change the degree of oxidation. In this case, they exert a catalytic effect on the exothermic redox reaction between the nitrate and the polymer. Such cases include the production of cobaltites, manganites, ferrites, cuprates, molybdates, compounds containing silver, etc.

It should be noted that the claimed method of forming powder particles, comprising mixing at least one type of metal salt, metal compound, inorganic ion or precursor solution with at least one type of organic solvent and direct ignition of the mixed solution with the creation of a self-sustaining flame for for obtaining powder particles (see, application for the grant of a patent of the Russian Federation No. 2003124957, publication date January 10, 2005; international publication number of this application WO 02/05718, publication date July 25, 2002 ). However, the disadvantage of this method is the excessive costs of the organic solvent.

We found that the decomposition of salts during heating of compositions, especially nitrate, occurs in the presence of polymers at significantly lower temperatures and proceeds very energetically, which is due to both the effects of complexation and the redox interaction of salts with the polymer (for nitrates). Nitro-polymer systems have a pronounced exothermic effect when decomposed instead of endothermic for pure salts. This allows you to reduce the temperature of synthesis of complex oxides below the temperature of intensive sintering and recrystallization, which is especially important when obtaining catalytic materials with a high specific surface area. The use of such systems for the synthesis of complex oxide materials also avoids high concentrations of residual carbon in the final products.

It has been established that the crystallization of salts is significantly affected not only by the nature of the polymer, but also by its molecular weight. The size of the salt crystals in the film and droplets during dispersion of polymer-salt solutions is associated with the size of the crystallites in the resulting complex oxide, which allows one to control the size of the latter by varying the molecular weight of the polymer.

Example 1, Obtaining a complex oxide YBA ₂ Cu ₃ O _7-δ (YBC) was carried out by preparing a polymer-salt solution, followed by applying it to an inert substrate, drying, separating the resulting film and burning it upon ignition. Polyvinyl alcohol with various molecular weights was used as the polymer. Nitrates of the corresponding metals were used as salts. The results are shown in the table below.

Table 1 Molecular Weight of Polyvinyl Alcohol The average crystal size of YBC, microns 15,000 2.8 22000 2.3 50,000 8.3 72000 9.8 100,000 10.0

The data obtained fully reflect the established dependence between the sizes of the crystals of nitrates proper in the films obtained from polymer-salt solutions and the sizes of oxide crystallites after the pyrolysis of films.

The dependence of the maximum crystal size of nitrates in the films formed from polymer-salt solutions containing polyvinyl alcohol, on the molecular weight of polyvinyl alcohol is shown in figure 1.

Figure 1 shows the data for the following salts: a - copper nitrate, b - yttrium nitrate, c - barium nitrate.

Example 2. Obtaining a complex oxide γBa ₂ Cu ₃ O _7-δ (YBC) was carried out by preparing a polymer-salt solution, followed by applying it to an inert substrate, drying, separating the resulting film and burning it when ignition was initiated.

Polyvinylpyrrolidone with various molecular weights was used as the polymer. Nitrates of the corresponding metals were used as salts. The results are shown in the table below. 2.

table 2 Molecular Weight of Polyvinylpyrrolidone The average crystal size of YBC, microns 25,000 7.2 360000 0.5

Example 3. The synthesis of complex oxide La _0.7 Sr _0.3 MnO ₃ was carried out by spraying aqueous solutions of nitrates of lanthanum, strontium and manganese in a thermochemical reactor. The temperature of the reactor is 650 ° C. The ratio of the components was selected based on the following conditions. The amount of metal nitrates taken was converted to an equivalent amount of nitric acid, based on the content of nitrate groups. For k = l, the stoichiometric amount of the polymer in the redox reaction involving the polymer and nitrates was taken:

During the experiments, the value k = 2 was chosen. The salt content in the initial solution was 5 wt.%. Polyvinyl alcohol was used as the polymer. The results are shown in the table below.

Table 3 Molecular Weight of Polyvinyl Alcohol The average crystallite size of La _0.7 Si _0.3 MnO ₃ , nm 15,000 40-50 50,000 60-70

The above examples confirm the feasibility of the present invention, leading to the implementation of the claimed technical result, namely, to create a more advanced method for producing oxides and complex metal oxides with the possibility of targeted regulation of the size of the obtained powdery products.

Claims (1)

A method for producing complex metal oxides in powder form, comprising obtaining an aqueous solution, which includes a water-soluble non-ionic polymer and salts containing metal ions, removing water from the resulting solution and subsequent thermal treatment of the obtained composite oxide precursor, characterized in that salts are used, easily decomposing thermally, polyvinyl alcohol or polyvinylpyrrolidone is used as a nonionic water-soluble polymer with a variable molecular weight nny aqueous solution is first applied to a inert substrate, dried to remove water from the resultant precursor film is formed is separated from the substrate, is carried out on the thermal effect resulting precursor complex oxide film by initiating ignition combustion, and to increase the crystal size YBa ₂ Cu ₃ O _{7- δ} of from 2.8 to 10 microns are used polyvinyl alcohol having a molecular weight of respectively of 15,000 to 100,000, for larger La _0,7 Sr _0,3 MnO ₃ crystallite size of from 40-50 to 60-70 nm is used polyvinyl alcohol having a molecular with a mass of 15,000 and 50,000, respectively, to obtain crystals of YBa ₂ Cu ₃ O _{7-δ with a} size of 7.2 μm and 0.5 μm, polyvinylpyrrolidone with a molecular weight of 25,000 and 360,000, respectively, is taken.

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