CN114225895A

CN114225895A - La-Fe-Al composite metal oxide, preparation method and application

Info

Publication number: CN114225895A
Application number: CN202210176876.6A
Authority: CN
Inventors: 王风; 李蒙蒙; 罗元; 张克强
Original assignee: Agro Environmental Protection Institute Ministry of Agriculture
Current assignee: Agro Environmental Protection Institute Ministry of Agriculture
Priority date: 2022-02-25
Filing date: 2022-02-25
Publication date: 2022-03-25
Anticipated expiration: 2042-02-25
Also published as: CN114225895B

Abstract

The invention relates to a La-Fe-Al composite metal oxide, a preparation method and application thereof, comprising the following components in volume ratio: LaCl₃30-35% of solution and FeCl₃23-30% of solution and AlCl₃3-12% of solution and 32-37% of citric acid solution, and the LaCl₃Solution, FeCl₃Solution, AlCl₃The solution is prepared from LaCl₃·7H₂O、FeCl₃·6H₂O、AlCl₃·6H₂O and citric acid solid powder are respectively dissolved in deionized water and mixed to obtain the product. The invention adopts the LaFeO prepared by the citric acid sol-gel method₃Used for adsorbing phosphate in water body due to formed LaFeO₃The alloy has high crystallinity and stable structure, and La and Fe have saturated coordination numbers and are not beneficial to adsorbing phosphatePreparation of LaFe_xAl_1‑xO₃The introduction of aluminum can increase the isoelectric point and specific surface area of the adsorbent, and in addition, the introduction of aluminum can increase the isoelectric point and specific surface area of the adsorbent due to Al³⁺The valence state is unchanged, the coordination saturation of La and Fe can be reduced, and the oxygen defect proportion of the material is increased, so that the adsorption performance is improved.

Description

La-Fe-Al composite metal oxide, preparation method and application

Technical Field

The invention relates to the technical field of adsorption materials, in particular to a La-Fe-Al composite metal oxide, a preparation method and application thereof.

Background

The eutrophication phenomenon of water has become a very serious environmental problem in China and even worldwide, for example, the American Yili lake has undergone a great amount of eutrophication events in the past half or more century, so that the aquatic ecosystem is seriously damaged, and large-scale algae outbreaks caused by eutrophication in the Chinese Taihu lake basin directly cause economic losses of $ 65 hundred million. Wherein, phosphorus is considered as a limiting factor causing water eutrophication, and the water eutrophication process is accelerated when the phosphorus concentration in the water exceeds 0.02mg/L, so that how to remove phosphorus elements in the water is of great significance.

The existing phosphorus removal method mainly comprises a biological method, a chemical precipitation method, an adsorption method and the like. Biological phosphorus removal has been applied to a plurality of countries, but microorganisms are sensitive to water quality change conditions, especially temperature and pH value, and aiming at low-concentration phosphorus-containing wastewater, microorganism metabolism is weakened, and phosphorus removal efficiency is very low. The chemical precipitation method can generally reduce the phosphorus concentration to 0.5-1.0 mg/L, and when the phosphorus concentration is reduced to below 0.5mg/L, a large amount of medicament needs to be added, so that the sludge yield and the treatment cost are rapidly increased. The adsorption method is considered to be a feasible phosphorus removal method due to the advantages of low cost, simple operation, environmental friendliness and high removal rate, but the core of the method lies in the development of excellent adsorption materials.

The perovskite oxide can be applied to the adsorption of phosphorus, and the chemical formula of the perovskite oxide is ABO₃(A-rare earth elements, e.g. La, Nd, Sm; B-transition metals, e.g. Fe, Mn, Co, Al, Cr) when the cation radius r_A>0.90Å，r_B>At 0.51A, the A site atoms are usually located at the center of the body and coordinated with 12O atoms and the B atoms are located at the vertices and coordinated with 6O atoms, forming an octahedral structure with a common oxygen-apical connection between the octahedra, so that many metal cations are in the perovskite ABO₃Stable performance is shown in the structure. This also results in many metal cations, although having a better affinity for oxoanions (e.g., phosphates), still exhibiting poor adsorption capabilities.In view of the above, how to develop an excellent adsorbent for improving the phosphate adsorption capacity is an urgent technical problem to be solved in the art.

Disclosure of Invention

The invention aims to overcome the defects in the prior art and provide an La-Fe-Al composite metal oxide, a preparation method and application, wherein the La-Fe-Al composite metal oxide is prepared by doping aluminum to replace iron_xAl_1-xO₃The introduction of aluminum can improve the isoelectric point and the specific surface area of the adsorbent, increase the oxygen defect proportion of the material and further improve the adsorption performance.

The invention is realized by the following technical scheme:

a La-Fe-Al composite metal oxide comprises the following components in percentage by volume: LaCl₃30-35% of solution and FeCl₃23-30% of solution and AlCl₃3-12% of solution and 32-37% of citric acid solution, and the LaCl₃Solution, FeCl₃Solution, AlCl₃The solution is prepared from LaCl₃•7H₂O、FeCl₃•6H₂O、AlCl₃•6H₂O and citric acid solid powder are respectively dissolved in deionized water and mixed to obtain the product.

According to the above technical solution, preferably, the LaCl₃Solution, FeCl₃Solution, AlCl₃The concentration of the solution is 0.2mol/L, and the concentration of the citric acid solution is 1 mol/L.

According to the technical scheme, the additive preferably comprises the following components in percentage by volume: LaCl₃Solution 33% FeCl₃28-30% of solution and AlCl₃3-5% of solution and 34% of citric acid solution.

According to the technical scheme, the additive preferably comprises the following components in percentage by volume: LaCl₃Solution 33% FeCl₃23-25% of solution and AlCl₃10-12% of solution and 32% of citric acid solution.

The invention also discloses a preparation method of the La-Fe-Al composite metal oxide, which comprises the following steps: a. respectively preparing 0.2mol/L of LaCl₃Solution, FeCl₃Solution, AlCl₃Solution and 1mol/L citric acid solution; b. according to the volume ratioSaid LaCl₃Solution, FeCl₃Solution, AlCl₃Mixing the solutions, and dropwise adding a citric acid solution under a stirring state; c. stirring for 1.5-2h, and evaporating for 24-30h in a constant-temperature water bath environment to obtain wet gel; d. drying the wet gel in an oven at the temperature of 110-130 ℃ for 24h to obtain dry gel; e. crushing the dry gel, putting the crushed dry gel into a tube furnace, heating to 400 ℃, roasting for 2h, heating to 800 ℃, roasting for 2h, cooling to room temperature to obtain a red powder solid product LaFe_xAl_1-xO₃。

According to the above technical solution, preferably, the water bath temperature in step c is 80 ℃.

According to the above technical solution, preferably, step e includes: the dry gel is crushed and transferred to a crucible and is placed into a tube furnace; opening the seals at two sides of the tube furnace; firstly, heating to 400 ℃ at the heating rate of 5 ℃ per minute, and roasting for 2 hours; then the temperature is increased to 800 ℃ and the mixture is calcined for 2h, and after the mixture is cooled to the room temperature, a red powder solid product LaFe is obtained_xAl_1-xO₃。

The invention also discloses application of the La-Fe-Al composite metal oxide in adsorbing phosphate, wherein the La-Fe-Al composite metal oxide adsorbs the phosphate under the environment that the pH value is 3-7.

The invention has the beneficial effects that:

the invention adopts the LaFeO prepared by the citric acid sol-gel method₃Used for adsorbing phosphate in water body due to formed LaFeO₃The crystallinity is high, the structure is stable, La and Fe have saturated coordination numbers and are not beneficial to adsorbing phosphate, therefore, the LaFe is prepared by doping aluminum to replace iron_xAl_1-xO₃The introduction of aluminum can increase the isoelectric point and specific surface area of the adsorbent, and in addition, the introduction of aluminum can increase the isoelectric point and specific surface area of the adsorbent due to Al³⁺The valence state is unchanged, the coordination saturation of La and Fe can be reduced, and the oxygen defect proportion of the material is increased, so that the adsorption performance is improved.

Drawings

FIG. 1 is a schematic diagram of XRD characterization analysis of test group S1, test group S2 and comparative group D in the present invention.

FIG. 2 is a graph showing the comparison of the adsorption amounts of phosphate at different pH levels among the test group S1, the test group S2, and the comparative group D according to the present invention.

Detailed Description

In order to make the technical solutions of the present invention better understood by those skilled in the art, the present invention will be further described in detail with reference to the accompanying drawings and preferred embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

A La-Fe-Al composite metal oxide comprises the following components in percentage by volume: LaCl₃30-35% of solution and FeCl₃23-30% of solution and AlCl₃3-12% of solution and 32-37% of citric acid solution, and the LaCl₃Solution, FeCl₃Solution, AlCl₃The solution is prepared from LaCl₃•7H₂O、FeCl₃•6H₂O、AlCl₃•6H₂O and citric acid solid powder are respectively dissolved in deionized water and mixed to obtain the product. Wherein, the LaCl₃Solution, FeCl₃Solution, AlCl₃The concentration of the solution is 0.2mol/L, and the concentration of the citric acid solution is 1 mol/L.

Based on the above examples, the present invention prefers the following two embodiments of volume ratio composition:

embodiment 1: LaCl₃Solution 33% FeCl₃28-30% of solution and AlCl₃3-5% of solution and 34% of citric acid solution;

embodiment 2: LaCl₃Solution 33% FeCl₃23-25% of solution and AlCl₃10-12% of solution and 32% of citric acid solution.

LaFeO prepared by citric acid sol-gel method is adopted in the research₃The perovskite is used for adsorbing phosphate in water, the citric acid sol-gel method has a plurality of advantages, but the corresponding perovskite structure can be formed only by calcining in air at 700-800 ℃, and LaFeO is formed due to the high calcining temperature and sufficient oxygen contact₃The perovskite has high crystallinity and stable structure, and La and Fe have saturated coordination numbers and are not beneficial to adsorbing phosphate. In view of this we prepared LaFe by doping with aluminum instead of iron_xAl_1-xO₃The introduction of aluminum to improve the adsorption performance has the following technical principle:

ion doping or partial substitution can cause valence alternation and oxygen defect, ion doping with different radii can generate different strain, Al³⁺Ionic radius ratio of Fe³⁺Small ionic radius, Al³⁺Ion substituted Fe³⁺After ions are generated, the inter-lattice ion distance is reduced, the grain size is reduced, namely, compressive strain occurs, and the lattice parameter is reduced; on the other hand, Al³⁺After doping, the lattice structure is distorted, the degree of the lattice distortion is increased along with the increase of the doping concentration, the dipole moment change is increased, the polarity of molecules is increased, the larger the polarity of the molecules is, the larger the Van der Waals force is, the Van der Waals force is taken as a main electrostatic attraction for adsorbing phosphate, phosphate ions can be effectively adsorbed, and the mass transfer power of the material for adsorbing phosphate is increased. LaFeO₃The medium oxygen exists mainly in two states, namely lattice oxygen and adsorbed oxygen, the adsorbed oxygen is formed by overflowing the lattice oxygen to form oxygen vacancy in the high-temperature synthesis process and adsorbing oxygen in the air in order to maintain the electrical neutrality of the system, but Fe in the high-temperature process³⁺May be oxidized into Fe⁴⁺In order to maintain charge balance, the overflow of lattice oxygen is limited, the amount of adsorbed oxygen is reduced, and at the moment, the unchanged valence state of aluminum ion is introduced, the aluminum ion is firstly combined with oxygen, and Fe⁴⁺Is reduced to Fe³⁺Even part of Fe³⁺Is reduced to Fe²⁺In order to maintain charge balance, the oxygen overflow of the crystal lattice is increased and the content of oxygen vacancies is increased, but the change tendency is opposite when too many aluminum ions are introduced because the charge change degree of the material itself is reduced and the oxygen vacancies are reduced.

The invention also discloses a preparation method of the La-Fe-Al composite metal oxide, which comprises the following steps:

a. accurately weighing a certain amount of LaCl according to a stoichiometric ratio₃•7H₂O（74.274g）、FeCl₃/6H₂O（54.06g）、AlCl₃•6H₂O (48.286 g) and citric acid solid powder (192.12 g) were dissolved in 1L of deionized water to prepare 0.2mol/L of LaCl₃、FeCl₃、AlCl₃Solution and 1mol/L citric acid solution.

b. LaCl is added into the mixture according to the following three groups of volume ratios₃Solution, FeCl₃Solution, AlCl₃Mixing the solutions, and dropwise adding a citric acid solution under stirring:

experimental group S1: 100mL of LaCl was taken out₃、90mL FeCl₃And 10mL AlCl₃The solutions are mixed with each other to form a mixed solution of La-Fe-Al, and 100mL of citric acid solution is dripped into the mixed solution under the condition of vigorous stirring;

experimental group S2: 100mL of LaCl was taken out₃、70mL FeCl₃And 30mL AlCl₃The solutions are mixed with each other to form a mixed solution of La-Fe-Al, and 100mL of citric acid solution is dripped into the mixed solution under the condition of vigorous stirring;

comparative group D: 100mL of LaCl was taken out₃、100mL FeCl₃Mixing the materials to form a La-Fe mixed solution, and dropwise adding 100mL of citric acid solution into the mixed solution under a violent stirring state;

c. stirring the three groups of mixed solutions for 1.5-2h under a magnetic stirrer, and evaporating for 24-30h in a constant-temperature water bath environment at 80 ℃ to obtain wet gel;

d. drying the wet gel in an oven at the temperature of 110-;

e. crushing the dry gel, transferring the crushed dry gel to a crucible, putting the crucible into a tubular furnace, opening the seals at two sides of the tubular furnace to ensure that sufficient air exists in the furnace, firstly heating to 400 ℃ at the heating rate of 5 ℃ per minute, roasting for 2h to remove organic matters per se, then heating to 800 ℃ to calcine for 2h, cooling to room temperature to obtain red powder solid products LaFe in an experiment group S1, an experiment group S2 and a comparison group D respectively_0.9Al_0.1O₃、LaFe_0.7Al_0.3O₃And LaFeO₃。

Wherein, the XRD characterization and analysis of FIG. 1 shows that the doped aluminum is pure LaFeO before and after doping₃The perovskite phase shows that Al in the experimental group S1 and the experimental group S2 is successfully doped into LaFeO₃In perovskite.

The invention also discloses application of the La-Fe-Al composite metal oxide in adsorbing phosphate, wherein the La-Fe-Al composite metal oxide adsorbs the phosphate under the environment that the pH value is 3-7. Specifically, the adsorption capacity of the test group S1, the test group S2 and the comparative group D for phosphate was verified through experiments in the following manner:

(1) preparing a phosphate solution: weigh 4.39g KH₂PO₄Prepare 1000mg/L phosphorus solution, take 30mL to 1L volumetric flask, dilute to 30mg/L with deionized water.

(2) Adjusting the pH value of the solution: the pH of the solution is adjusted to 2-12 with 1mol/L NaOH and 1mol/L HCl.

(3) Weighing: 0.02g of LaFeO was weighed₃、LaFe_0.9Al_0.1O₃And LaFe_0.7Al_0.3O₃In a 100ml Erlenmeyer flask.

(4) Adding a solution: 50ml of a phosphorus solution having a pH of 2 to 12 and a concentration of 30mg/L was added to each flask.

(5) Culturing: placing the triangular flask into a constant-temperature shaking incubator with the rotation speed of 180r/min and the temperature of 25 ℃ for culture.

(6) Measurement: and taking out a sample after 24 hours, standing, extracting supernate, filtering the supernate with a 0.45-micrometer filter membrane, and measuring the phosphate concentration at the wavelength of 700nm by adopting an ammonium molybdate spectrophotometry.

As can be seen from fig. 2, the initial pH of the solution has a great influence on the adsorption of phosphate by the three adsorbents of experimental group S1, experimental group S2, and comparative group D. Under the strong acid condition (pH = 2), the three adsorbents are dissolved, and the obvious observation is that the adsorption quantity is low and the adsorption effect is poor; when the pH is =3-4, the adsorption quantity is remarkably improved, and LaFeO₃Maximum adsorption (pH = 3) 31.11mg/g, LaFe_0.9Al_0.1O₃And LaFe_0.7Al_0.3O₃The maximum adsorption amounts (pH = 4) were 43.06 and 50.83mg/g, respectively, and it was also observed that the adsorption amount gradually increased with increasing aluminum doping amount, probably because phosphate was preferentially bonded to aluminum under acidic conditions; as the pH increases, the phosphate in solution is predominantly HPO₄ ^2-Form exists, HPO₄ ^2-Has larger adsorption energy, so that the adsorption capacity of the three adsorbents is gradually reduced, but the LaFe_0.9Al_0.1O₃And LaFe_0.7Al_0.3O₃Still better than LaFeO₃The qualitative improvement shows that the doped aluminum can cause the change of the physical and chemical properties of the material, and the isoelectric point, the specific surface area and the oxygen defect number of the material are improved; when the pH =7-9, the more doped aluminum content, the gradually decreased adsorption amount, again demonstrating that phosphate bonds preferentially to aluminum under acidic conditions and to lanthanum under neutral and alkaline conditions; however, at pH =10-11, LaFe_0.7Al_0.3O₃Adsorption capacity ratio LaFe_0.9Al_0.1O₃High, still kept around 20mg/g, probably because the oxygen defect number increases with the doping aluminum content, and can compensate OH in the solution^-The impact caused by the heat; at pH =12, the adsorption capacity of the three materials is significantly reduced, indicating that OH is present under strongly alkaline conditions^-Can occupy the adsorption position on the surface of the adsorbent, and compete with phosphate to be unfavorable for the adsorption process. In conclusion, the La-Fe-Al composite metal oxide has better effect of removing phosphorus element in water body for water quality in acid environment.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims

1. The La-Fe-Al composite metal oxide is characterized by comprising the following components in percentage by volume: LaCl₃30-35% of solution and FeCl₃23-30% of solution,AlCl₃3-12% of solution and 32-37% of citric acid solution, and the LaCl₃Solution, FeCl₃Solution, AlCl₃The solution is prepared from LaCl₃•7H₂O、FeCl₃•6H₂O、AlCl₃•6H₂O and citric acid solid powder are respectively dissolved in deionized water and mixed to obtain the product.

2. The La-Fe-Al composite metal oxide according to claim 1, wherein the LaCl is₃Solution, FeCl₃Solution, AlCl₃The concentration of the solution is 0.2mol/L, and the concentration of the citric acid solution is 1 mol/L.

3. The La-Fe-Al composite metal oxide according to claim 2, comprising the following components by volume: LaCl₃Solution 33% FeCl₃28-30% of solution and AlCl₃3-5% of solution and 34% of citric acid solution.

4. The La-Fe-Al composite metal oxide according to claim 2, comprising the following components by volume: LaCl₃Solution 33% FeCl₃23-25% of solution and AlCl₃10-12% of solution and 32% of citric acid solution.

5. A preparation method of La-Fe-Al composite metal oxide is characterized by comprising the following steps: a. respectively preparing 0.2mol/L of LaCl₃Solution, FeCl₃Solution, AlCl₃Solution and 1mol/L citric acid solution; b. the LaCl is added according to the volume ratio₃Solution, FeCl₃Solution, AlCl₃Mixing the solutions, and dropwise adding a citric acid solution under a stirring state; c. stirring for 1.5-2h, and evaporating for 24-30h in a constant-temperature water bath environment to obtain wet gel; d. drying the wet gel in an oven at the temperature of 110-130 ℃ for 24h to obtain dry gel; e. crushing the dry gel, putting the crushed dry gel into a tube furnace, heating to 400 ℃, roasting for 2h, heating to 800 ℃, roasting for 2h, cooling to room temperature to obtain a red powder solid product LaFe_xAl_1-xO₃。

6. The method of preparing La-Fe-Al composite metal oxide according to claim 5, wherein the water bath temperature in step c is 80 ℃.

7. The method of preparing La-Fe-Al composite metal oxide according to claim 5, wherein step e comprises: the dry gel is crushed and transferred to a crucible and is placed into a tube furnace; opening the seals at two sides of the tube furnace; firstly, heating to 400 ℃ at the heating rate of 5 ℃ per minute, and roasting for 2 hours; then the temperature is increased to 800 ℃ and the mixture is calcined for 2h, and after the mixture is cooled to the room temperature, a red powder solid product LaFe is obtained_xAl_1-xO₃。

8. Use of a La-Fe-Al composite metal oxide for adsorbing phosphate, wherein the La-Fe-Al composite metal oxide adsorbs phosphate at a pH of 3 to 7.