CN113024232A

CN113024232A - Light-heavy rare earth mixed high-entropy rare earth silicate compact block and preparation method thereof

Info

Publication number: CN113024232A
Application number: CN202110283659.2A
Authority: CN
Inventors: 田志林; 李斌; 陈峙霖; 郑丽雅
Original assignee: Sun Yat Sen University
Current assignee: Sun Yat Sen University
Priority date: 2021-03-17
Filing date: 2021-03-17
Publication date: 2021-06-25
Anticipated expiration: 2041-03-17
Also published as: CN113024232B

Abstract

The invention provides a light and heavy rare earth mixed high-entropy rare earth silicate compact block, which has the chemical formula as follows: (Ho)_0.25Lu_0.25Yb_0.25Eu_0.25)₂SiO₅The block is represented by Ho₂O₃、Lu₂O₃、Yb₂O₃、Eu₂O₃、SiO₂The material is prepared by wet mixing, high-temperature reaction, wet ball milling, cold press molding, cold isostatic pressing and high-temperature sintering. The light and heavy rare earth mixed high-entropy rare earth silicate compact block disclosed by the invention is high in solid solubility, good in high-temperature stability, high in density, simple in preparation method process, high in production efficiency, high in safety and energy-saving.

Description

Light-heavy rare earth mixed high-entropy rare earth silicate compact block and preparation method thereof

Technical Field

The invention belongs to the technical field of ceramic materials for an aero-engine environmental barrier coating, and particularly relates to a light-heavy rare earth mixed high-entropy rare earth silicate compact block and a preparation method thereof.

Background

The thrust-weight ratio of the aircraft engine is a development direction of the future aircraft industry, and the temperature of a front inlet of a turbine is required to be increased to realize a high thrust-weight ratio, so that the working temperature of a combustion chamber, a turbine blade and other hot end parts is continuously increased. At present, the blade material of the aeroengine is a high-temperature alloy material, and the further temperature rise of the front inlet of the turbine reaches the temperature bearing limit of the nickel-based high-temperature alloy, so that the nickel-based high-temperature alloy is difficult to meet the working requirement of the engine. Silicon-based non-oxide ceramics and composite materials thereof (such as silicon-based ceramic materials) have excellent high-temperature thermal and mechanical properties, and are expected to replace traditional high-temperature alloys to be used as a new generation of hot end part materials of aircraft engines.

Under the dry combustion environment, a layer of SiO is generated on the surface of the silicon-based ceramic material₂The film plays a good role in protection and can prevent the further oxidation of the silicon-based material. However, in a combustion environment containing water vapor, the silicon-based ceramic reacts with the water vapor to form volatile Si (OH)₄Causing degradation of material properties. The Environmental Barrier Coatings (EBC) have the characteristics of good molten salt corrosion resistance, water oxygen corrosion resistance and the like, and the problem can be hopefully solved by coating the EBC on the surface of a hot end part of an engine.

The rare earth silicate ceramic material has excellent steam corrosion resistance and CMAS (CaO-MgO-Al) resistance₂O₃-SiO₂) Corrosion performance and low thermal expansion coefficient, and is a hot candidate material for the new generation of environmental barrier coating. Some rare earth monosilicates and rare earth disilicates meet the basic requirements as environmental barrier coatings for silicon-based non-oxide ceramics. However, the properties of single-phase rare earth silicates are not balanced in all aspects, and candidate materials which completely meet the performance requirements of environmental barrier coatings cannot be found at present, so that the materials need to be optimally designed.

The high-entropy ceramic is formed by applying the design idea of high-entropy alloy to ceramic and replacing single cations in the traditional ceramic with several equimolar or nearly equimolar cations. The self characteristics of various elements and the interaction among the elements can combine the excellent performances of the elements, so that the high-entropy ceramic has the excellent performances of all components. The common high-entropy ceramics are mainly high-entropy rare ceramicsBulk earth silicates, e.g. high entropy rare earth monosilicates (Yb) of heavy rare earths_0.25Y_0.25Lu_0.25Er_0.25)₂SiO₅Bulk, rare earth disilicate (Yb)_0.2Y_0.2Lu_0.2Sc_0.2Gd_0.2)₂Si₂O₇Bulk, rare earth monosilicate (Y)_0.25Ho_0.25Er_0.25Yb_0.25)₂SiO₅Blocks, and the like. However, the existing preparation method of the high-entropy rare earth silicate block has the problems of complex process, low efficiency, low density of the block, single type of rare earth elements (all heavy rare earth), and the like.

Disclosure of Invention

In order to overcome the defects of the prior art, the invention provides a light-heavy rare earth mixed high-entropy rare earth silicate compact block which is high in solid solubility, good in high-temperature stability and high in density, and the preparation method is simple in process, high in production efficiency, high in safety and energy-saving.

In order to achieve the purpose, the invention adopts the technical scheme that:

the invention provides a light and heavy rare earth mixed high-entropy rare earth silicate compact block, which has the chemical formula as follows: (Ho)_0.25Lu_0.25Yb_0.25Eu_0.25)₂SiO₅Wherein Ho (holmium), Lu (lutetium) and Yb (ytterbium) are heavy rare earth elements, and Eu (europium) is light rare earth element.

The invention also provides a preparation method of the light and heavy rare earth mixed high-entropy rare earth silicate compact block, which comprises the following steps:

s1, according to Ho₂O₃:Lu₂O₃:Yb₂O₃:Eu₂O₃:SiO₂Weighing the raw materials according to the molar ratio of 1:1:1:1: 4;

s2, uniformly mixing the raw materials in the step S1 by adopting a wet mixing method, drying and sieving to obtain mixed raw materials;

s3, reacting the mixed raw materials obtained in the step S2 at high temperature to obtain light and heavy rare earth mixed high-entropy rare earth silicate ceramic particles;

s4, carrying out wet ball milling on the heavy rare earth mixed high-entropy rare earth silicate ceramic particles obtained in the step S3, drying and sieving to obtain light rare earth mixed high-entropy rare earth silicate ceramic powder;

s5, carrying out cold press molding and cold isostatic pressing on the light and heavy rare earth mixed high-entropy rare earth silicate ceramic powder obtained in the step S4 to obtain a light and heavy rare earth mixed high-entropy rare earth silicate block blank;

and S6, sintering the light and heavy rare earth mixed high-entropy rare earth silicate block blank obtained in the step S5 at a high temperature to obtain a heavy rare earth mixed high-entropy rare earth silicate compact block.

Preferably, the wet mixing in step S2 takes ethanol as a medium, the rotation speed is 100-300r/min, and the time is 4-12 h.

Preferably, the high-temperature reaction in the step S3 is a reaction at 1500-1700 ℃ for 2-8h in an air atmosphere.

Preferably, the wet ball milling in step S4 uses ethanol as a medium, the rotation speed is 100-.

Preferably, the pressure of the cold press molding in the step S5 is 10-30MPa, and the dwell time is 1-5 min; the pressure of the cold isostatic pressing is 100-250MPa, and the pressure maintaining time is 10-30 min.

Preferably, the temperature of the high-temperature sintering in the step S5 is 1400-1750 ℃, and the holding time is 2-12 h.

Preferably, the Ho of step S1₂O₃、Lu₂O₃、Yb₂O₃、Eu₂O₃、SiO₂The purity of (A) is 99.9% -99.99%.

Preferably, the sieving in steps S2 and S4 is through a 40-120 mesh sieve.

Preferably, the ball milling pot and the milling balls for the wet mixing in the step S2 and the wet ball milling in the step S4 are both made of zirconia or agate.

Compared with the prior art, the invention has the beneficial effects that:

the invention provides a light and heavy rare earth mixed high-entropy rare earth silicate compact block, which has the chemical formula as follows: (Ho)_0.25Lu_0.25Yb_0.25Eu_0.25)₂SiO₅The block is represented by Ho₂O₃、Lu₂O₃、Yb₂O₃、Eu₂O₃、SiO₂The material is prepared by wet mixing, high-temperature reaction, wet ball milling, cold press molding, cold isostatic pressing and high-temperature sintering. The invention has the following advantages:

(1) the preparation process is simple in process, high in safety and energy-saving.

(2) In the preparation process of the light and heavy rare earth mixed high-entropy rare earth silicate compact block, the method of cold isostatic pressing and pressureless sintering is adopted, the production efficiency is high, and a plurality of samples can be prepared simultaneously: the common hot-pressing sintering can prepare only one sample at a time; the cold isostatic pressing and pressureless sintering method of the invention can be used for firing a plurality of samples in one furnace.

(3) The light and heavy rare earth mixed high-entropy rare earth silicate compact block disclosed by the invention is high in solid solubility, good in high-temperature stability and high in density, and can reach more than 96%.

Drawings

FIG. 1 shows (Ho)_0.25Lu_0.25Yb_0.25Eu_0.25)₂SiO₅X-ray diffraction patterns of (a);

FIG. 2 is (Ho)_0.25Lu_0.25Yb_0.25Eu_0.25)₂SiO₅Scanning electron microscope images of the surface;

FIG. 3 is (Ho)_0.25Lu_0.25Yb_0.25Eu_0.25)₂SiO₅Scanning electron microscope images of the fractures.

Detailed Description

The following further describes the embodiments of the present invention. It should be noted that the description of the embodiments is provided to help understanding of the present invention, but the present invention is not limited thereto. In addition, the technical features involved in the embodiments of the present invention described below may be combined with each other as long as they do not conflict with each other.

The experimental procedures in the following examples were carried out by conventional methods unless otherwise specified, and the test materials used in the following examples were commercially available by conventional methods unless otherwise specified.

Example 1 dense block of light and heavy rare earth mixed high-entropy rare earth silicate

The chemical formula of the light and heavy rare earth mixed high-entropy rare earth silicate compact block is as follows: (Ho)_0.25Lu_0.25Yb_0.25Eu_0.25)₂SiO₅Wherein Ho (holmium), Lu (lutetium) and Yb (ytterbium) are heavy rare earth elements, and Eu (europium) is light rare earth element.

The preparation method of the light and heavy rare earth mixed high-entropy rare earth silicate compact block comprises the following steps:

(1) according to Ho₂O₃:Lu₂O₃:Yb₂O₃:Eu₂O₃:SiO₂Weighing raw materials according to the molar ratio of 1:1:1:1:4, Ho₂O₃、Lu₂O₃、Yb₂O₃、Eu₂O₃、SiO₂The purity of the raw material is 99.9-99.99%;

(2) wet mixing the raw materials by using a ball mill, taking absolute ethyl alcohol as a medium, taking a ball milling tank and a grinding ball as zirconia or agate materials, mixing, drying and sieving by using a 80-mesh sieve to obtain a mixed raw material, wherein the rotating speed is 200r/min and the time is 8 h;

(3) placing the mixed raw materials in a high-temperature reaction furnace, and reacting for 5h at 1600 ℃ in the air atmosphere to obtain light and heavy rare earth mixed high-entropy rare earth silicate ceramic particles;

(4) carrying out wet ball milling on the light and heavy rare earth mixed high-entropy rare earth silicate ceramic particles, wherein the ball milling takes absolute ethyl alcohol as a medium, a ball milling tank and a milling ball are made of zirconia or agate materials, the rotating speed is 200r/min, the time is 8h, and the light and heavy rare earth mixed high-entropy rare earth silicate ceramic particles are obtained by drying and sieving through a 80-mesh sieve after ball milling;

(5) cold press molding is carried out on the light rare earth and heavy rare earth mixed high-entropy rare earth silicate ceramic powder, the pressure of the cold press molding is 20MPa, and the pressure maintaining time is 3 min; then carrying out cold isostatic pressing, wherein the pressure of the cold isostatic pressing is 150MPa, and the pressure maintaining time is 20min, so as to obtain a light-heavy rare earth mixed high-entropy rare earth silicate block blank;

(6) placing the light and heavy rare earth mixed high-entropy rare earth silicate ceramic blocky blank into a high-temperature reaction furnace, sintering at 1650 ℃ for 8h in the air atmosphere to obtain a heavy rare earth mixed high-entropy rare earth silicate compact blocky body (Ho)_0.25Lu_0.25Yb_0.25Eu_0.25)₂SiO₅。

For (Ho) prepared as described above_0.25Lu_0.25Yb_0.25Eu_0.25)₂SiO₅Performing X-ray diffraction spectrum analysis (with mixed powder as contrast), and using X-ray diffractometer (PANALYTIC EMPYREAN), wherein incident light is Cu Ka 1 ray filtered by monochromator, and wavelength is

The working voltage is 40kV, the working current is 45mA, and the scanning speed is 10 degrees/min. Wherein PDF #40-0383 is single-phase rare earth silicate Ho₂SiO₅The mixed powder is Ho₂SiO₅、Lu₂SiO₅、Yb₂SiO₅、Eu₂SiO₅Mechanically mixing four kinds of rare earth silicate according to an equal molar ratio.

As can be found from the diffraction pattern of FIG. 1, (Ho)_0.25Lu_0.25Yb_0.25Eu_0.25)₂SiO₅The peak of (A) is consistent with that of a standard PDF card, and the peak position is shifted only due to the lattice distortion of the high-entropy ceramic; the peaks of the mixed powder almost match those of the PDF card, but if the mixed powder is observed in a certain angle range under magnification, the mixed powder is found to have distinct peaks, for example, 21 ° to 24 ° and 27 ° to 29 °, indicating that there are a plurality of phases in the mixed powder. Prepared in this example (Ho)_0.25Lu_0.25Yb_0.25Eu_0.25)₂SiO₅The pure-phase light-heavy rare earth mixed high-entropy rare earth silicate is free of impurities and high in solid solubility, and is not a mechanical mixture of several kinds of rare earth silicates. Furthermore, althoughThe preparation temperature of the sample is high, the time is long, but other reactions do not occur to generate impurities, which indicates that the high-temperature stability of the sample is good.

At the same time, scanning electron microscope (SU8010) was used to prepare (Ho)_0.25Lu_0.25Yb_0.25Eu_0.25)₂SiO₅The surface of (2) was scanned by electron microscopy, and as can be seen from the results in FIG. 2, the sample surface was very dense with few voids.

Scanning electron microscope (SU8010) is used to measure the (Ho) obtained_0.25Lu_0.25Yb_0.25Eu_0.25)₂SiO₅The fracture of the sample is subjected to electron microscope scanning, and as can be seen from the result of fig. 3, the fracture holes of the sample are very few, and the pore diameter is below 10 μm, which indicates that the density of the sample is very high.

In addition, for the prepared (Ho)_0.25Lu_0.25Yb_0.25Eu_0.25)₂SiO₅And (3) carrying out density calculation: established using Materials Studio (Ho)_0.25Lu_0.25Yb_0.25Eu_0.25)₂SiO₅Obtaining a cell of theoretical density rho₀＝6.69934g/cm³(ii) a (Ho) of the present example was measured by Archimedes drainage method_0.25Lu_0.25Yb_0.25Eu_0.25)₂SiO₅Has a density of rho of 6.527g/cm₃Density eta is rho/rho₀

It can be calculated that (Ho) prepared in this example_0.25Lu_0.25Yb_0.25Eu_0.25)₂SiO₅The density (ratio of actual measured density to theoretical density) of 97.43%.

Example 2A dense block of light and heavy rare earth mixed high-entropy rare earth silicate

(2) wet mixing the raw materials by using a ball mill, taking absolute ethyl alcohol as a medium, taking a ball milling tank and a grinding ball as zirconia or agate materials, mixing, drying and sieving by using a 40-mesh sieve to obtain a mixed raw material, wherein the rotating speed is 100r/min and the time is 4 h;

(3) placing the mixed raw materials in a high-temperature reaction furnace, and reacting at 1500 ℃ for 8h in the air atmosphere to obtain light and heavy rare earth mixed high-entropy rare earth silicate ceramic particles;

(4) carrying out wet ball milling on the light and heavy rare earth mixed high-entropy rare earth silicate ceramic particles, wherein the ball milling takes absolute ethyl alcohol as a medium, a ball milling tank and a milling ball are made of zirconia or agate materials, the rotating speed is 100r/min, the time is 12 hours, and the light and heavy rare earth mixed high-entropy rare earth silicate ceramic particles are obtained by drying and sieving through a 40-mesh sieve after ball milling;

(5) cold press molding is carried out on the light rare earth and heavy rare earth mixed high-entropy rare earth silicate ceramic powder, the pressure of the cold press molding is 10MPa, and the pressure maintaining time is 5 min; then carrying out cold isostatic pressing, wherein the pressure of the cold isostatic pressing is 100MPa, and the pressure maintaining time is 30min, so as to obtain a light-heavy rare earth mixed high-entropy rare earth silicate block blank;

(6) placing the light and heavy rare earth mixed high-entropy rare earth silicate ceramic blocky blank into a high-temperature reaction furnace, sintering in the air atmosphere at the sintering temperature of 1400 ℃ for 12h to obtain a heavy rare earth mixed high-entropy rare earth silicate compact block (Ho)_0.25Lu_0.25Yb_0.25Eu_0.25)₂SiO₅。

Prepared by this example (Ho)_0.25Lu_0.25Yb_0.25Eu_0.25)₂SiO₅The X-ray diffraction result, the surface and fracture scanning electron microscope result of the composite material are consistent with those of the embodiment 1, and the compactness is more than 96%.

Example 3A dense block of light and heavy rare earth mixed high-entropy rare earth silicate

(2) wet mixing the raw materials by using a ball mill, taking absolute ethyl alcohol as a medium, taking a ball milling tank and a grinding ball as zirconia or agate materials, mixing, drying and sieving by using a 120-mesh sieve to obtain a mixed raw material, wherein the rotating speed is 300r/min and the time is 4 h;

(3) placing the mixed raw materials in a high-temperature reaction furnace, and reacting for 2h at 1700 ℃ in the air atmosphere to obtain light and heavy rare earth mixed high-entropy rare earth silicate ceramic particles;

(4) carrying out wet ball milling on the light and heavy rare earth mixed high-entropy rare earth silicate ceramic particles, wherein the ball milling takes absolute ethyl alcohol as a medium, a ball milling tank and a milling ball are made of zirconia or agate materials, the rotating speed is 300r/min, the time is 4h, and the light and heavy rare earth mixed high-entropy rare earth silicate ceramic particles are obtained by drying and sieving through a 120-mesh sieve after ball milling;

(5) cold press molding is carried out on the light rare earth and heavy rare earth mixed high-entropy rare earth silicate ceramic powder, the pressure of the cold press molding is 30MPa, and the pressure maintaining time is 1 min; then carrying out cold isostatic pressing, wherein the pressure of the cold isostatic pressing is 250MPa, and the pressure maintaining time is 10min, so as to obtain a light-heavy rare earth mixed high-entropy rare earth silicate block blank;

(6) placing the light and heavy rare earth mixed high-entropy rare earth silicate ceramic blocky blank into a high-temperature reaction furnace, sintering in the air atmosphere at 1750 ℃ for 2h to obtain a heavy and heavy rare earth mixed high-entropy rare earth silicate compact blocky body (Ho)_0.25Lu_0.25Yb_0.25Eu_0.25)₂SiO₅。

The embodiments of the present invention have been described in detail, but the present invention is not limited to the described embodiments. It will be apparent to those skilled in the art that various changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, and the scope of protection is still within the scope of the invention.

Claims

1. The light and heavy rare earth mixed high-entropy rare earth silicate compact block is characterized in that the chemical formula of the light and heavy rare earth mixed high-entropy rare earth silicate compact block is as follows: (Ho)_0.25Lu_0.25Yb_0.25Eu_0.25)₂SiO₅。

2. A preparation method of a light-heavy rare earth mixed high-entropy rare earth silicate compact block is characterized by comprising the following steps:

3. The method for preparing the light and heavy rare earth mixed high-entropy rare earth silicate compact block as claimed in claim 2, wherein the wet mixing in step S2 uses ethanol as a medium, and the rotation speed is 100-300r/min, and the time is 4-12 h.

4. The method for preparing the light and heavy rare earth mixed high-entropy rare earth silicate compact block according to claim 2, wherein the high-temperature reaction in the step S3 is 1500-1700 ℃ in an air atmosphere for 2-8 h.

5. The method for preparing the light and heavy rare earth mixed high-entropy rare earth silicate compact block as claimed in claim 2, wherein the wet ball milling in step S4 uses ethanol as a medium, and the rotation speed is 100-.

6. The method for preparing the light and heavy rare earth mixed high-entropy rare earth silicate compact block according to claim 2, wherein the pressure of the cold press molding in the step S5 is 10-30MPa, and the pressure maintaining time is 1-5 min; the pressure of the cold isostatic pressing is 100-250MPa, and the pressure maintaining time is 10-30 min.

7. The method for preparing the light and heavy rare earth mixed high-entropy rare earth silicate compact block as claimed in claim 2, wherein the temperature of the high-temperature sintering in the step S5 is 1400-1750 ℃, and the holding time is 2-12 h.

8. The method for preparing the dense block of the light-heavy rare earth-mixed high-entropy rare earth silicate according to claim 2, wherein the Ho in the step S1₂O₃、Lu₂O₃、Yb₂O₃、Eu₂O₃、SiO₂The purity of (A) is 99.9% -99.99%.