CN110743551A

CN110743551A - Ammonia porous copper-iron bimetallic catalyst synthesized by photocatalysis and application thereof

Info

Publication number: CN110743551A
Application number: CN201910938293.0A
Authority: CN
Inventors: 王梁炳; 侯婷婷; 辛月; 张重阳
Original assignee: Central South University
Current assignee: Central South University
Priority date: 2019-09-30
Filing date: 2019-09-30
Publication date: 2020-02-04
Anticipated expiration: 2039-09-30
Also published as: CN110743551B

Abstract

The invention discloses a photocatalytic synthesis ammonia porous copper-iron bimetallic catalyst and application thereof, wherein the molecular formula is Cu_xFe_yWherein x is 80-99, y is 1-20, and the porous copper-iron bimetallic catalyst is used for etching Cu by a sulfuric acid solution₂₁Fe₇₉And (5) obtaining the alloy powder. The invention selectively etches away the raw material Cu by using a sulfuric acid solution₂₁Fe₇₉Fe in the alloy powder, thereby preparing the nano porous copper-iron bimetallic catalyst for synthesizing ammonia by photocatalysis. By controlling the amount of the sulfuric acid, the porous nano copper-iron bimetallic catalyst with different Cu and Fe molar ratios can be obtained. The preparation method is simple and efficient, the components are easy to control, particularly when the molar ratio of Cu to Fe is 96:4, high ammonia yield is obtained, the catalyst can be recycled, 100 percent of original reaction activity is almost retained after 10 times of cyclic reaction, and the method has extremely high reaction rateShould be stable.

Description

Ammonia porous copper-iron bimetallic catalyst synthesized by photocatalysis and application thereof

Technical Field

The invention belongs to the technical field of ammonia photocatalytic synthesis, and relates to a porous copper-iron bimetallic catalyst for ammonia photocatalytic synthesis and application thereof.

Background

Ammonia is an extremely important chemical product, and concerns agriculture, energy and the environment. Global annual NH₃The yield can reach more than one hundred million tons, and most of the yield is used for fertilizer production to promote agricultural development; besides, ammonia is also used as a raw material for producing other chemical products, such as synthetic fibers, nitric acid, nitrogen-containing inorganic salts, and the like, in the aspects of organic chemistry and inorganic chemistry. At the same time, NH₃The material has obvious energy carrier property due to the characteristics of high hydrogen content, large energy density, easy liquefaction and the like, and can be used as a potential good energy storage material. Industrially, mainly using H₂N fixation by Haber-Bosch procedure₂To synthesize ammonia. The process is based on iron-based catalysts, which require high temperatures>673K) High pressure (>20atm) and has extremely high energy consumption, and the energy consumed by the industrial synthesis of ammonia per year accounts for about 1.4 percent of the total energy supplied globally every year according to statistics. While H required for the process₂Mainly comes from the reforming of coal or natural gas and is easy to generate a large amount of CO₂It has extremely bad influence on the ecological environment.

The nitrogen-fixing enzyme is a substance capable of dissolving N at room temperature₂Conversion to NH₃The biological enzyme of (1). In the process of biological nitrogen fixation, MoFe protein in nitrogen fixation enzyme can effectively adsorb N₂And activating N by accepting electrons transferred from Fe protein₂. Therefore, the reasonable design of the photocatalyst structure can realize the ammonia synthesis process at room temperature, which is inspired by azotase. N is a radical of₂The nitrogen-nitrogen triple bond (N.ident.N) with extremely high stability in the nitrogen-nitrogen triple bond severely limits N₂Efficiency of light fixation. Theoretically, the N ≡ N bond can be weakened, its bond length increased and its bond energy decreased by either donating electrons from the bonding orbital or accepting electrons to the anti-bonding orbital to be N ≡ N bond₂Provides a kinetic pathway that can be accomplished. Thus, in general, two separate units are present together in the photocatalyst, i.e. for the adsorption of N₂Active site and thermionic electron donor.

The metal with plasmon resonance effect is an ideal donor of thermal electrons, and can be used for N₂The field of optical fixation. When light is incident on the surface of the metal nanoparticles, ifWhen the frequency of the incident photons is consistent with the natural frequency of the surface electrons, the photons can be captured by the electrons which are vibrated together, and the free electrons on the surface of the metal nano particles are coupled with the captured photoelectrons to form a special electromagnetic mode, so that the local resonance phenomenon of the free electrons is generated. At the resonant frequency, the enhanced photo-species interaction results in an increase in the electric field at the metal surface, promoting a greater number of energetic charge carriers (electron-hole pairs). Metals having a plasmon resonance effect in the visible light region are mainly Au, Ag, Cu, and the like. Among them, the easy corrosion and easy oxidation of Cu nanocrystals in water and even in air severely limits the application of Cu nanocrystals in plasma catalysis.

Nanoporous metals are a class of functional materials with interconnected three-dimensional porous network structures. The nano porous metal has wider application in the field of catalysis due to larger specific surface area, rich high-index crystal faces and high-density atomic steps and kinks. More importantly, nanoporous metals exhibit higher stability during catalysis than nanoparticles. Based on the size dependence of the thermodynamic equilibrium of metals, the increased stability of nanoporous metals may be due to their surface energy and low tension. Therefore, the nano-porous copper-based catalyst with the plasmon resonance effect is developed and applied to N₂Light fixation is of great significance.

Disclosure of Invention

In order to solve the technical problem of designing the nano-porous copper-based catalyst in the prior art, the invention aims to provide the photo-catalytic synthesis ammonia porous copper-iron bimetallic catalyst prepared by using the etching method, the copper-iron ratio in the nano-porous copper-iron bimetallic catalyst is controlled by controlling the amount of sulfuric acid, the preparation method is simple and efficient, and the obtained catalyst has high activity and stable property and can be repeatedly used.

In order to realize the technical purpose, the invention provides a photocatalytic synthesis ammonia porous copper-iron bimetallic catalyst with a molecular formula of Cu_xFe_yWherein x is 80-99, y is 1-20, and the porous copper-iron bimetallic catalyst is used for etching Cu by a sulfuric acid solution₂₁Fe₇₉Alloy powderAnd (5) obtaining the product.

Cu in the present invention₂₁Fe₇₉The alloy powder can be prepared by a conventional gas atomization method or directly purchased, and is not mechanical mixed powder of copper powder and iron powder.

Preferably, in the formula, x is 96 and y is 4.

Preferably, the sulfuric acid etching process specifically comprises: with H in sulfuric acid solution₂SO₄And Cu₂₁Fe₇₉The mass ratio of the alloy powder is 1.0-1.5: 1 mixing the two, heating to 80 ℃ for reaction for 30min, and carrying out solid-liquid separation, washing and drying to obtain the porous copper-iron bimetallic catalyst.

Preferably, the sulfuric acid solution and Cu₂₁Fe₇₉The liquid-solid ratio of the alloy powder is 15-25 mL/g.

The invention also provides the application of the photocatalytic synthesis ammonia porous copper-iron bimetallic catalyst, and the application of the photocatalytic synthesis ammonia porous copper-iron bimetallic catalyst in the photocatalytic synthesis of ammonia comprises the following specific processes: in the photocatalytic synthesis of ammonia, a porous copper-iron bimetallic catalyst is added into deionized water to obtain a suspension, nitrogen is blown into the suspension, and the ammonia synthesis reaction is carried out under the irradiation of a xenon lamp light source.

In the present invention, Cu as a raw material is selectively etched away by using sulfuric acid₂₁Fe₇₉Fe in the alloy powder, thereby preparing the nano porous copper-iron bimetallic catalyst for synthesizing ammonia by photocatalysis. By controlling the amount of the sulfuric acid, the porous nano copper-iron bimetallic catalyst with different Cu and Fe molar ratios can be obtained. The preparation method is simple and efficient, the components are easy to control, particularly when the molar ratio of Cu to Fe is 96:4, high ammonia yield is obtained, the catalyst can be recycled, 100% of original reaction activity is almost retained after 10 times of cyclic reaction, and the reaction stability is extremely high.

Drawings

FIG. 1 shows Cu obtained in example 2 of the present invention₉₆Fe₄Sample and unetched Cu₂₁Fe₇₉SEM image of alloy powder, wherein a is Cu₉₆Fe₄Sample, b is Cu₂₁Fe₇₉And (3) alloying powder.

FIG. 2 shows Cu obtained in example 1 of the present invention₈₀Fe₂₀Cu obtained in example 2₉₆Fe₄Cu obtained in example 3₉₉Fe₁Comparative example 2 Cu₅₇Fe₄₃And Cu obtained in comparative example 3_99.9Fe_0.1Graph comparing yield at full spectrum and visible range.

FIG. 3 shows Cu obtained in example 1 of the present invention₈₀Fe₂₀Cu obtained in example 2₉₆Fe₄Cu obtained in example 3₉₉Fe₁Comparative example 2 Cu₅₇Fe₄₃And Cu obtained in comparative example 3_99.9Fe_0.1N of (A)₂-temperature programmed desorption profile.

FIG. 4 shows Cu obtained in example 2 of the present invention₉₆Fe₄The stability chart of recycling (1).

Detailed Description

The invention will be further illustrated with reference to the following specific examples. It should be noted that these examples are only for illustrating the present invention and are not intended to limit the scope of the present invention. Modifications and adaptations of the present invention may occur to those skilled in the art and are intended to be within the scope of the present invention.

Example 1

A method for preparing a nano porous copper-iron bimetallic catalyst by using an etching method comprises the following steps:

Cu₈₀Fe₂₀preparing a nano porous copper-iron bimetallic catalyst:

(1) with H in sulfuric acid solution₂SO₄And Cu₂₁Fe₇₉The mass ratio of the alloy powder is 1.136: 1 mixing the two: firstly, 19.32mL of sulfuric acid with the concentration of 0.6mol/L is prepared and added into a 100mL vacuum thick-wall pressure-resistant bottle, and then 1g of Cu is added₂₁Fe₇₉Adding the bimetal powder while stirring;

(2) placing the vacuum thick-wall pressure-resistant bottle into an oil bath pan, stirring and heating the system at 80 ℃ for 30 min;

(3) after cooling to room temperature, the obtained product was washed several times with water until the pH of the supernatant was about 7, and then centrifuged at 3500rpm for 10min to collect the powder;

(4) vacuum drying the collected powder at 60 ℃ for 1h to obtain the porous copper-iron bimetallic catalyst Cu₈₀Fe₂₀。

Photocatalytic synthesis of ammonia:

(1) taking 10mg of prepared Cu₈₀Fe₂₀Adding the nano porous copper-iron bimetallic catalyst into 20mL of deionized water;

(2) at room temperature at about 30mL min^-1Blowing nitrogen gas into the suspension at a speed of 30min, and then irradiating at an intensity of 250mW cm^-2The lower side of the xenon lamp is irradiated and stirred for 30 min;

(3) the yield of synthetic ammonia after the reaction was found to be 109. mu. mol. g_cat. ^–1·h^–1。

Example 2

Cu₉₆Fe₄Preparing a nano porous copper-iron bimetallic catalyst:

(1) with H in sulfuric acid solution₂SO₄And Cu₂₁Fe₇₉The mass ratio of the alloy powder is 1.205: 1 mixing the two: firstly, 20.5mL of sulfuric acid with the concentration of 0.6mol/L is prepared and added into a 100mL vacuum thick-wall pressure-resistant bottle, and then 1g of Cu is added₂₁Fe₇₉Adding the bimetal powder while stirring;

(4) vacuum drying the collected powder at 60 ℃ for 1h to obtain the porous copper-iron bimetallic catalyst Cu₉₆Fe₄。

As shown in FIG. 1, Cu₂₁Fe₇₉The surface of the alloy powder is of a compact structure; after etching with a sulfuric acid solution, Cu was observed₉₆Fe₄The pore size of the obvious nano-porous structure is about 50nm-200 nm.

Photocatalytic synthesis of ammonia:

(1) taking 10mg of prepared Cu₉₆Fe₄Adding the nano porous copper-iron bimetallic catalyst into 20mL of deionized water;

(2) at room temperature at about 30mL min^-1Nitrogen was bubbled through the suspension at a rate of 30 min. Then the light intensity is 250mW cm^-2The lower side of the xenon lamp is irradiated and stirred for 30 min;

(3) the yield of synthetic ammonia after the reaction was determined to be 342. mu. mol. g_cat. ^–1·h^–1。

As shown in FIG. 3, the peak at about 80 ℃ is vs. N₂The peak at 150-500 ℃ belongs to the pair N₂Chemisorption of (1), wherein Cu₉₆Fe₄The maximum area of the chemisorption peak of (A) indicates the maximum value for N₂The most strongly chemisorbed.

The recycling experiment:

(1) centrifuging the reacted suspension at 8000rpm for 10min, taking the supernatant for synthetic ammonia detection, washing the precipitate with deionized water and washing again, and then taking the precipitate as a catalyst for next cycle of photocatalytic synthetic ammonia experiment;

(2) taking Cu after each circulation experiment washing₉₆Fe₄Adding the nano-porous copper-iron bimetallic catalyst into 20mL of deionized water, and reacting at room temperature for about 30mL min^-1Nitrogen was bubbled through the suspension at a rate of 30 min. Then the light intensity is 250mW cm^-2The mixture was vigorously stirred for 30min while being irradiated under a xenon lamp.

(3) The above operation was repeated for a total of 10 cycles.

As shown in FIG. 4, after 10 cycles of reaction, Cu was present₉₆Fe₄Almost 100% of the original reactivity was retained, indicating that Cu₉₆Fe₄The nano porous copper-iron bimetallic catalyst has extremely high reaction stability.

Example 3

Cu₉₉Fe₁Preparing a nano porous copper-iron bimetallic catalyst:

(1) with H in sulfuric acid solution₂SO₄And Cu₂₁Fe₇₉Alloy (I)The mass ratio of the powder is 1.264: 1 mixing the two solutions, preparing 21.5mL of sulfuric acid with the concentration of 0.6mol/L, adding the sulfuric acid into a 100mL vacuum thick-wall pressure-resistant bottle, and then adding 1g of Cu₂₁Fe₇₉Adding the bimetal powder while stirring;

(4) vacuum drying the collected powder at 60 ℃ for 1h to obtain the porous copper-iron bimetallic catalyst Cu₉₉Fe₁。

Photocatalytic synthesis of ammonia:

(1) taking 10mg of prepared Cu₉₉Fe₁Adding the nano porous copper-iron bimetallic catalyst into 20mL of deionized water;

(3) the yield of synthetic ammonia after the reaction was found to be 146. mu. mol. g_cat. ^–1·h^–1。

Comparative example 1

Direct use of unetched Cu₂₁Fe₇₉Photocatalytic synthesis of ammonia from bimetallic powder:

(1) 10mg of unetched Cu were taken₂₁Fe₇₉Adding the bimetal powder into 20mL of deionized water;

(3) the yield of synthetic ammonia after the reaction was found to be 8.32. mu. mol. g_cat. ^–1·h^–1。

Comparative example 2

Cu₅₇Fe₄₃Preparing a nano porous copper-iron bimetallic catalyst:

(1) with H in sulfuric acid solution₂SO₄And Cu₂₁Fe₇₉The mass ratio of the alloy powder is 0.883: 1 mixing the two. Firstly preparing 15mL of 0.6mol/L sulfuric acid, adding the sulfuric acid into a 100mL vacuum thick-wall pressure-resistant bottle, and then adding 1g of Cu₂₁Fe₇₉Adding the bimetal powder while stirring;

(4) vacuum drying the collected powder at 60 ℃ for 1h to obtain the porous copper-iron bimetallic catalyst Cu₅₇Fe₄₃。

Photocatalytic synthesis of ammonia:

(1) taking 10mg of prepared Cu₅₇Fe₄₃Adding the nano porous copper-iron bimetallic catalyst into 20mL of deionized water;

(3) the yield of synthetic ammonia after the reaction was found to be 52. mu. mol. g_cat. ^–1·h^–1。

Comparative example 3

Cu_99.9Fe_0.1Preparing a nano porous copper-iron bimetallic catalyst:

(1) with H in sulfuric acid solution₂SO₄And Cu₂₁Fe₇₉The mass ratio of the alloy powder is 1.89: 1 mixing the two: preparing 32.2mL of sulfuric acid with the concentration of 0.6mol/L, adding the sulfuric acid into a 100mL vacuum thick-wall pressure-resistant bottle, and then adding 1g of Cu₂₁Fe₇₉Adding the bimetal powder while stirring;

(4) vacuum drying the collected powder at 60 ℃ for 1h to obtain the porous copper-iron bimetallic catalyst Cu_99.9Fe_0.1。

Photocatalytic synthesis of ammonia:

(1) taking 10mg of prepared Cu_99.9Fe_0.1Adding the nano porous copper-iron bimetallic catalyst into 20mL of deionized water;

(3) the yield of synthetic ammonia after the reaction was found to be 5. mu. mol. g_cat. ^–1·h^–1。

Claims

1. A photocatalytic synthesis ammonia porous copper-iron bimetallic catalyst is characterized in that: molecular formula is Cu_xFe_yWherein x is 80-99, y is 1-20, and the porous copper-iron bimetallic catalyst is used for etching Cu by a sulfuric acid solution₂₁Fe₇₉And (5) obtaining the alloy powder.

2. The photocatalytic synthesis ammonia porous copper iron bimetallic catalyst of claim 1, characterized by: in the formula, x is 96, and y is 4.

3. The photocatalytic synthesis ammonia porous copper-iron bimetallic catalyst according to claim 1 or 2, characterized in that: the specific process of the sulfuric acid etching is as follows: with H in sulfuric acid solution₂SO₄And Cu₂₁Fe₇₉The mass ratio of the alloy powder is 1.0-1.5: 1 mixing the two, heating to 80 ℃ for reaction for 30min, and carrying out solid-liquid separation, washing and drying to obtain the porous copper-iron bimetallic catalyst.

4. The photocatalytic synthesis ammonia porous copper iron bimetallic catalyst of claim 3, characterized by: the sulfuric acid solution and Cu₂₁Fe₇₉Liquid-solid ratio of alloy powder15 to 25 mL/g.

5. Use of the photocatalytically synthesized ammonia porous copper-iron bimetallic catalyst of any one of claims 1 to 4, characterized in that: the method is used for synthesizing ammonia by photocatalysis, and comprises the following specific processes: in the photocatalytic synthesis of ammonia, a porous copper-iron bimetallic catalyst is added into deionized water to obtain a suspension, nitrogen is blown into the suspension, and the ammonia synthesis reaction is carried out under the irradiation of a xenon lamp light source.