CN112359374B

CN112359374B - Application of composite material

Info

Publication number: CN112359374B
Application number: CN202011316165.1A
Authority: CN
Inventors: 赵玉平
Original assignee: Xinjiang Dingchen Technology Co ltd
Current assignee: Xinjiang Dingchen Technology Co ltd
Priority date: 2020-11-22
Filing date: 2020-11-22
Publication date: 2023-12-01
Anticipated expiration: 2040-11-22
Also published as: CN112359374A

Abstract

The application is thatProvides a copper-based composite material for electrocatalytic reduction of CO ₂ The spiny copper is formed on the surface of the copper base through hydrothermal treatment, the specific surface area and the active site of the electrode material can be remarkably improved, the electrode is stable, and the spiny copper is not easy to peel off and fall off; the service life of the copper-based alloy can be prolonged while the high ethylene conversion rate is ensured, the Faraday efficiency of the electrochemical conversion method is more than 60% and the ethylene selectivity is more than or equal to 40% under the electrolysis voltage of-1.8V vs Ag/AgCl.

Description

Application of composite material

Technical Field

The application belongs to the field of electrochemistry, and particularly relates to a preparation method of a high-service-life copper-based composite material, which is particularly suitable for application in the field of preparing ethylene by electrocatalytic reduction of carbon dioxide.

Technical Field

CO ₂ Stable in chemical structure, and thus CO ₂ Activation of the molecule is very difficult and thus difficult to participate in the reaction, which has been conventionally converted using severe reaction conditions such as high temperature and pressure. In general, researchers have employed chemical reforming, mineralization, enzymatic catalysis, photocatalysis, electrocatalysis, etc. to overcome the larger activation energy barrier of CO 2. In these methods, H is not required due to the mild electrochemical reduction reaction conditions ₂ As a raw material, the reaction pH is close to neutral and excellent clean energy compatibility is attracting attention.

Electrochemical reduction is a means of reducing CO2 under relatively mild external conditions by applying an electric current such that CO2 is reduced at the cathode surface. Electrochemical reduction has the following advantages: the reduction product can be controlled by adjusting the electrolysis voltage, the electrolysis temperature and the electrolyte type; the electrolyte is convenient to recycle; the structure of the electrolytic cell is simple and convenient to manufacture, and the electrolytic cell is generally carried out at normal temperature; the electric energy for electrolysis can be generated by renewable energy sources such as solar energy, wind energy and geothermal energy; the electrochemical reaction system is compact, modularized and adjusted according to the needs, and is easy to be used in industrial factory building.

Since there are many factors affecting the electrochemical reduction of CO2, such as electrode type, solvent type, electrolysis voltage, pressure, temperature, etc., the obtained products are also various, such as methanol, formic acid, methane, carbon monoxide, ethylene, etc., and various metals are classified into four major categories according to the product distribution rule thereof.

(I) The first kind of metal, copper (Cu), as a unique catalyst shows remarkable catalytic performance and can be used for converting CO ₂ Conversion to hydrocarbons and oxygenates is the only one that can be significantly effectedRate will CO ₂ Metal electrocatalysts for reduction to hydrocarbons or oxygenated hydrocarbons, such as methane, ethylene, ethanol, and propanol.

(II) the second category of metals, noble metals such as gold (Au), silver (Ag), zinc (Zn), palladium (Pd), and gallium (Ga), are selective to carbon monoxide (CO), and are produced primarily from CO.

(III) third class of metals tin (Sn), lead ((Pb), mercury (Hg), indium (In), cadmium (Cd), etc., which are mainly formate, are produced as formic acid (HCOOH) and formate ((HCOO) ^- ) Is a catalyst of the optimum type.

(N) a fourth metal such as nickel (Ni), iron (Fe), platinum (Pt) and titanium (Ti) and the like, and only generates hydrogen evolution reaction in a stable state to generate hydrogen (H) ₂ ) Without CO ₂ Is a reducing power of (a) to (b).

Among the various catalysts for electrochemical reduction of COZ, copper is considered to be the most promising catalyst for the production of hydrocarbons such as methane and ethylene. In recent years, high-selectivity copper-based electrocatalysts have attracted extensive attention from students at home and abroad because of their high energy density and ethylene as a chemical raw material.

CN202010628183 discloses a dendritic copper electrode with hydrophobic surface, a preparation method and application thereof. The copper electrode provided by the application comprises a gas diffusion layer and a copper layer deposited on the surface of the gas diffusion layer; the microscopic morphology of the copper layer is dendritic. The surface of the copper electrode provided by the application is composed of regular copper dendrites, shows good hydrophobicity, can effectively prevent excessive contact of electrolyte, avoids 'flooding' of the electrode, and improves the stability of the electrode; and dendrite-shaped copper can also efficiently enrich cations in the electrolyte to form a local high electric field, so that the carbon-carbon coupling rate is improved, and the electrode shows excellent electrocatalytic CO2 reduction activity.

CN201911278128 uses copper alloy material with amorphous structure as catalyst, and CO2 is subjected to electrochemical reaction to obtain carbon-containing compound. The application adopts copper alloy material with amorphous structure as catalyst to directly prepare carbon-containing compounds such as alcohol, acid and ketone by electrocatalytic reduction of CO 2. The copper alloy material can be prepared into various macroscopic forms such as a block form, a powder form, a film form and the like, can be directly used as an electrocatalytic electrode material to be applied to a CO2 electrocatalytic reduction cell, and simultaneously improves the electrocatalytic activity and stability of the catalyst, thereby improving the performance and efficiency of the electrolytic cell. The synthesis method provided can effectively exert the synergistic catalytic performance among the catalysts by regulating and controlling the composition and the structure of the copper alloy material with the amorphous structure, further regulate and control the types of products, and selectively obtain different carbon-containing compounds such as alcohol, acid, ketone and the like.

CN201910713686 discloses a copper-based carbon dioxide electrocatalytic material and a preparation method thereof, wherein the method comprises the following steps: mixing an oxidant solution and an organic ligand solution to prepare a mixed solution; placing metal copper into the mixed solution, enabling the organic ligand to be adsorbed on part of specific crystal faces of the metal copper, and enabling the crystal faces of the metal copper which are not adsorbed by the organic ligand to undergo oxidation reaction; and (3) cleaning the metal copper after the oxidation reaction, removing the organic ligand adsorbed on the crystal face of the metal copper, and performing electrochemical reduction to obtain the OD-Cu carbon dioxide catalytic material with more specific crystal faces. According to the method, organic ligands with different types and concentrations are added in the oxidation process, so that on one hand, the regulation and control of different crystal forms of the OD-Cu material can be realized; on the other hand, the prepared OD-Cu material has the advantages of high surface roughness, high grain boundary density and the like, can preferentially expose crystal faces, and can remarkably improve the catalytic activity of the material on CO2 and the selectivity on a multi-carbon product.

CN201810661930 discloses a preparation method of flower-shaped copper oxide, which comprises the following steps: a) Mixing an oxidant, a morphology control agent, a hydrophilic group surfactant and an alkaline compound in water to obtain an initial solution; the morphology control agent is selected from sodium tungstate, potassium tungstate, sodium molybdate, urea or ethylenediamine; b) Immersing the cleaned copper into the initial solution for hydrothermal reaction to obtain flower-like copper oxide. The application also provides a method for photoelectrocatalytic reduction of CO2 by using the flower-shaped copper oxide as an electrode. The application provides a method for preparing flower-like copper oxide by taking elemental copper as a copper source, and the flower-like copper oxide prepared by the method can be directly used as an electrode for photoelectrocatalytic reduction of CO2 without additional molding treatment.

CN201310254758 discloses a flower-like copper oxide/iron oxide nanotube catalyst and a preparation method thereof, firstly volcanic-like iron oxide nanotubes are grown on an iron substrate in situ by an electrochemical anodic oxidation method, then copper oxide with a flower-like structure is deposited on the iron oxide substrate by a pulse electrodeposition method, and the flower-like copper oxide/iron oxide nanotube catalyst is obtained after calcination. The catalyst has good photoelectrocatalysis performance, realizes the coupling of two reactions of water splitting and CO2 reduction, reduces CO2 photoelectrocatalytically, and is subjected to gas chromatography detection analysis, and the products are methanol and ethanol.

The following problems are evident from the above patents: (1) As the most excellent ethylene selective catalyst, there are few research directions aimed at improving ethylene selectivity, and ethylene is the most important energy hydrogenation raw material in chemical production; (2) life of electrocatalytic electrodes was not investigated; (3) the catalytic activity is to be improved.

Disclosure of Invention

Based on the problems, the application aims to provide a method for electrocatalytic reduction of CO by copper-based composite material ₂ The electrode structure and the preparation technology can improve the service life of the electrode while ensuring high ethylene conversion rate.

The method comprises the following steps:

(1) Pretreating the copper-based alloy;

(2) The copper-containing solution is used as electrolyte, copper-based material is used as cathode, and electrochemical deposition reduction is carried out under extremely high negative bias.

(3) Chemically reducing copper nanowire seed crystals at a high temperature;

(4) Hydro-thermal treatment to obtain thorn-shaped copper-based composite material

(5) And (5) oxidizing.

Wherein the pretreatment in the step (1) is polishing and inorganic degreasing;

wherein the copper-containing electrolyte in the step (2) comprises copper sulfate, sulfuric acid, chloride ions and a surfactant, and the anode is an inert electrode or pure copper;

wherein the solution used in the high-temperature chemical reduction in the step (3) is a mixed solution of copper acetate and glycerol;

wherein the solution used by the water heating in the step (4) is consistent with the solution in the step (3), and is in a closed state,

wherein the oxidizing solution used in the step (5) is a mixed solution of ammonia water and copper carbonate.

The Faraday efficiency of the electrochemical conversion method of the copper-based alloy is more than 60% and the ethylene selectivity is more than or equal to 40% under the electrolysis voltage of-1.8V vs Ag/AgCl.

Further, the copper-based alloy is copper-nickel-white copper alloy, and the shape is bar-shaped or plate-shaped.

Further, the sanding is sequentially carried out by using 200# sand paper, 600# sand paper and 1200# sand paper.

Further, the degreasing is 15g/L Na ₂ CO ₃ 、 10g/L Na ₃ PO ₄ ^. 12H ₂ O、10 g/L Na ₂ SiO ₃ At a temperature of 50 ^o C, time 2min.

Further, the copper-containing electrolyte: 140-150g/L CuSO ₄ ^. 5H ₂ O；30-35g/L H ₂ SO ₄ ；40-45g/L Cl ^- The method comprises the steps of carrying out a first treatment on the surface of the 0.5-1g/L APEO; temperature of 25-30 DEG C ^o C, performing operation; direct current constant voltage-13V for 5s-10s.

Further, the solution used in the high temperature chemical reduction of step (3): 3-5M anhydrous copper acetate glycerol solution at 300-350 ^o C, in a non-sealing state, the time is 15-20min.

Further, the hydrothermal temperature in the step (4) is 110-120 DEG C ^o C, the time is 12-24h.

Furthermore, the reaction kettles in the step (3) and the step (4) are stainless steel lining-free hydrothermal reaction kettles, and before the step (4), nitrogen is used for exhausting air in the reaction kettles in the step (3).

Further, the concentration of the ammonia water in the step (5) is 100-120ml/L of an ammonia water solution with the mass fraction of 25 wt%, 40g/L of copper carbonate is 3-5min, and the temperature is15-20 ^o C。

Further, the Gao Shoutong-based composite material is produced by CO ₂ Electrocatalytic reduction electrodes.

(1) Regarding the selection of the substrate: the copper-based alloy is copper-nickel-white copper alloy and is copper-nickel binary alloy, wherein the nickel content is 5-10wt.%, the binary alloy has better corrosion resistance under the premise of meeting the mechanical strength, and the nickel in the binary alloy is in CO ₂ No catalytic reduction of CO in electrocatalytic processes ₂ I.e. nickel does not cause any side reactions, does not affect the conversion of ethylene with high selectivity according to the application, if brass (Cu-Zn) or bronze (Cu-Sn) alloys are chosen, zn will be electrocatalytically CO-produced, and tin will be electrocatalytically formic acid, which is detrimental to the object of the application.

(2) Pretreatment of a substrate: including polishing and degreasing, wherein polish: the 200# sand paper, the 600# sand paper and the 1200# sand paper are sequentially used for sanding, so that the surface of the abrasive paper is smooth, the purpose of the abrasive paper is to reduce roughness, remove macroscopic defects such as scratches, oxide layers, corrosion marks, rust spots and the like on the surface, improve the surface smoothness, enable the surface to reach enough smoothness, and the degreasing is 15g/L Na ₂ CO ₃ 、 10g/L Na ₃ PO ₄ ^. 12H ₂ O、10 g/L Na ₂ SiO ₃ At a temperature of 50 ^o C, for 2min, the degreasing fluid used in the application does not contain strong alkaline sodium hydroxide, mainly because Cu+NaOH+O2 can form Na2CuO ₂ While Na2CuO ₂ Can be decomposed into CuO proper oxide film in water, is unfavorable for robbing the surface, and comprises a hot water washing step, a cold water washing step, the surface of a piece to be plated is washed by deionized water heated to at least 45-50 ℃, the residual alkali liquor is removed, and then the piece to be plated is washed by cold deionized water.

(3) Electrochemical deposition reduction is carried out with extremely high negative bias: in the method, copper-base alloy is taken as a cathode, an inert or pure copper electrode is taken as an anode, direct current is conducted, copper ions are reduced at the cathode, but because extremely high negative bias is applied to a copper-base alloy plate, severe hydrogen evolution reaction is caused, and hydrogen exists in the form of bubbles at the cathodeIn the place where hydrogen bubbles appear, no metal ions exist, namely, no copper ion deposition reaction can occur, so that the reaction of electrodeposited copper forming a compact structure is consistent at a cathode to form cavities, as shown in fig. 1, 2, 3 and 4, holes with different densities are formed on the surface of the copper-based alloy along with the increase of time, the density of the holes is closely related to voltage and time, the specific surface area of a cathode material is obviously increased in the cathode deposition process, and the specific surface area of the polished copper-based alloy is approximately equal to 0m ² /g; after 10s of cathodic deposition, the specific surface rises to 9m ² Per g, if the time is increased, a cathode current density of more than 100m can be obtained by reasonably adjusting ² Three-dimensional porous copper material per gram, which, however, is high in specific surface area by the abovementioned process, is also active for electrocatalytic reduction of CO ₂ But the catalytic activity conversion, ethylene selectivity and Faraday efficiency are low, and the preparation method can be referred to in the prior art.

The application has the main purpose of obtaining a porous copper layer in a short time of 5s-10s, and aims at digging pits, facilitating the subsequent seed crystal attachment, and finally obtaining the CO2 electrocatalytic material with high strength, bonding strength and long service life through subsequent hydrothermal reaction pit burying.

The copper-containing electrolyte of the present application: 140-150g/L CuSO ₄ ^. 5H ₂ O；30-35g/L H ₂ SO ₄ ；40-45g/L Cl ^- The method comprises the steps of carrying out a first treatment on the surface of the 0.5-1g/L APEO, where the theoretical CuSO ₄ ^. 5H ₂ O may be about 230g/L, but uSO is lowered in view of the solubility leading to precipitation of copper sulfate ₄ ^. 5H ₂ O is 140-150g/L; the sulfuric acid can obviously reduce the resistance of the plating solution in the plating solution, can prevent copper sulfate from being hydrolyzed to form copper hydroxide precipitate, the concentration of the sulfuric acid is lower than that of actual copper plating, and is generally more than 40g/L in industry, so that a smooth plating layer is formed, and when the concentration of the sulfuric acid is lower, a rough plating layer is easy to form and is required by the application; APEO surfactant is added in the application, mainly to improve the surface tension of the plating solution and avoid excessive overflow of hydrogen bubbles.

Finally, the process should be optimally placed in a stationary state without any stirring assistance.

(4) Regarding high temperature chemical reduction copper nanowire seed: the process uses glycerol solution of 3-5M anhydrous copper acetate, wherein glycerol has a certain reducibility at normal temperature, but has no capability of reducing copper sulfate, and the temperature is 300-350 ℃ at high temperature ^o Under the condition C, the glycerol has extremely strong reducing capability, copper sulfate can be reduced into copper polyhedral particles through no electrochemistry, the particles can be adsorbed into pits in the step (2) to serve as crystal seeds, a reaction kettle is not sealed in the process, but evaporation loss of a solution is required to be reduced as much as possible, and the main density of the process is that seed crystals are formed.

(5) The spiny copper-based composite material is obtained by hydro-thermal treatment, and the hydro-thermal temperature in the process is 110-120 DEG C ^o C, the time is 12-24 hours, before the step (4), nitrogen is used for exhausting the air in the reaction kettle in the step (3), the nano copper can be shaped and grown by a hydrothermal method, the nano wire is obtained, and then the copper-based electrode material with high specific surface area is obtained.

To further illustrate the above process, an extremely fine copper nickel wire was used as the substrate, as shown in FIG. 5; electrochemical deposition reduction is carried out by extremely high negative bias to form a porous copper layer on the surface of the copper layer, as shown in figure 6; then forming copper crystals in the pore channels through high-temperature electrochemical-free reduction, as shown in figure 7; the spiny copper-based composite material obtained by the hydro-thermal treatment is shown in fig. 8, and the spiny copper on the surface of the copper material can be more clearly seen from fig. 9.

(6) Regarding oxidation: the purpose of the oxidation is to form CuO _X The layer, the oxidation state metal has rich crystal boundary on the catalyst surface, and the specific crystal surface shows stronger catalytic activity and selectivity, under the condition of CO2 electrocatalysis, the oxidation layer can be electrochemically reduced into a metal layer, the process activates the metal catalyst, forms specific low coordination active sites on the catalyst surface, simultaneously blocks the reaction sites of competing Hydrogen Evolution Reaction (HER), improves the product selectivity, the reduction activity of the copper-based electrode has stronger dependence on the initial thickness of the copper-oxygen layer, which indicates that the metal oxidation state has strong dependence on the electrocatalysisThe oxidation performance has positive significance, the thickness of the oxide layer obtained by the method is 0.1-0.2 microns, the concentration of ammonia water is 100-120ml/L of ammonia water solution with mass fraction of 25 wt%, the time is 3-5min, and the temperature is 15-20 ^o C, after oxidation, the thorn-shaped structure slightly converges, as shown in figure 10, and XPS test is carried out on oxidized copper oxide-based material, as shown in figure 11 fitting chart, so as to further prove that CuO _X Is present.

The beneficial technical effects are as follows:

(1) The electrode is stable, and the obtained thorn-shaped copper is not easy to peel off and fall off.

(2) The thorn-shaped copper material obviously improves the contact specific surface area of the reactant and the electrode, and provides rich sites for catalytic reduction of CO 2.

（3）CuO _X The layer effectively inhibits hydrogen evolution reaction, and oxidation state is preferentially combined with H ions for reduction, so that the combination reaction of H and H is avoided.

(4) Has extremely high ethylene selectivity, high conversion rate and high Faraday efficiency.

Drawings

FIG. 1 is a 2s SEM image of electrochemical deposition at a streamer constant voltage of-13V according to the application.

FIG. 2 is a 5s SEM image of electrochemical deposition at a streamer constant voltage of-13V according to the application.

FIG. 3 is a 7s SEM image of electrochemical deposition at a streamer constant voltage of-13V according to the application.

FIG. 4 is a 10s SEM image of electrochemical deposition at a streamer constant voltage of-13V according to the application.

Fig. 5 is a TEM image of the application on a copper wire.

FIG. 6 is a 10s TEM image of electrochemical deposition at a streamer constant voltage of-13V according to the application.

Fig. 7 is a TEM image of the application without electrochemical reduction at high temperature.

Fig. 8 is a TEM image of the hydrothermal process of the present application.

Fig. 9 is an SEM image of a spiny copper-based composite obtained by the hydrothermal treatment of the present application.

FIG. 10 is an SEM image of a spiny copper-based composite obtained by the oxidation treatment of the present application.

FIG. 11 is an XPS fit of a barbed copper-based composite obtained by the oxidation treatment of the present application.

Description of the embodiments

The following describes in detail the examples of the present application, which are implemented on the premise of the technical solution of the present application, and detailed embodiments and specific operation procedures are given, but the scope of protection of the present application is not limited to the following examples.

Example 1

Copper-based composite material for electrocatalytic reduction of CO ₂ The copper-based composite material is prepared by the following steps:

(1) Pretreating the copper-based alloy; the copper-based alloy is copper-nickel-white copper alloy.

Wherein the pretreatment in the step (1) comprises polishing and inorganic degreasing: polishing is as follows: sanding was performed using 200#, 600#, 1200# sandpaper in sequence.

Degreasing to 15g/L Na ₂ CO ₃ 、 10g/L Na ₃ PO ₄ ^. 12H ₂ O、10 g/L Na ₂ SiO ₃ At a temperature of 50 ^o C, time 2min.

(2) And taking the copper-containing solution as electrolyte, taking the copper-based alloy as a cathode, and carrying out electrochemical deposition reduction under extremely high negative bias.

Wherein the copper-containing electrolyte in the step (2) comprises copper sulfate, sulfuric acid, chloride ions and a surfactant, the anode is an inert electrode or pure copper, and the copper-containing electrolyte comprises: 140g/L CuSO ₄ ^. 5H ₂ O；30g/L H ₂ SO ₄ ；40g/L Cl ^- The method comprises the steps of carrying out a first treatment on the surface of the 0.5g/L APEO; temperature 25 ^o C, performing operation; direct current constant voltage-13V for 5s.

(3) High temperature chemical reduction copper nanowire seed.

Wherein the solution used in the high-temperature chemical reduction in the step (3) is a mixed solution of copper acetate and glycerol, and the temperature of the glycerol solution of 3M anhydrous copper acetate is 300 ^o And C, in a non-sealing state, the time is 15min.

(4) And performing hydrothermal treatment to obtain the thorn-shaped copper-based composite material.

The solution used by the water heating in the step (4) is consistent with the solution in the step (3), and the air in the reaction kettle in the step (3) is exhausted by using nitrogen before the step (4) in a closed state.

The hydrothermal temperature in the step (4) is 110 ^o C, time is 12h.

(5) And (5) oxidizing.

Ammonia water solution with ammonia water concentration of 100ml/L and mass fraction of 25 wt%, 40g/L copper carbonate for 3min at 15 ^o C。

Example 2

Wherein the copper-containing electrolyte in the step (2) comprises copper sulfate, sulfuric acid, chloride ions and a surfactant, the anode is an inert electrode or pure copper, and the copper-containing electrolyte comprises: 145g/L CuSO ₄ ^. 5H ₂ O；32.5g/L H ₂ SO ₄ ；42.5g/L Cl ^- The method comprises the steps of carrying out a first treatment on the surface of the 0.75g/L APEO; temperature 27 ^o C, performing operation; DC constant voltage-13V, time 8s.

(3) High temperature chemical reduction copper nanowire seed.

Wherein the solution used in the high-temperature chemical reduction in the step (3) is copper acetate or tricyclopediaAlcohol mixture, 4M anhydrous copper acetate glycerol solution at 320 ^o And C, in a non-sealing state, the time is 17.5min.

The hydrothermal temperature in the step (4) is 115 ^o C, time is 18h.

(5) And (5) oxidizing.

Aqueous ammonia solution with concentration of 115ml/L and mass fraction of 25wt.%, 40g/L copper carbonate, time of 4min and temperature of 17.5 ^o C。

Designated as S-2 sample.

Example 3

Wherein the copper-containing electrolyte in the step (2) comprises copper sulfate, sulfuric acid, chloride ions and a surfactant, the anode is an inert electrode or pure copper, and the copper-containing electrolyte comprises: 150g/L CuSO ₄ ^. 5H ₂ O； 35g/L H ₂ SO ₄ ；45g/L Cl ^- The method comprises the steps of carrying out a first treatment on the surface of the 1g/L APEO; temperature 30 ^o C, performing operation; DC constant voltage-13V, time 10s.

(3) High temperature chemical reduction copper nanowire seed.

Wherein the solution used in the high-temperature chemical reduction in the step (3) is a mixed solution of copper acetate and glycerol, and the temperature of the 5M anhydrous copper acetate glycerol solution is 350 DEG C ^o And C, in a non-sealing state, the time is 20min.

The hydrothermal temperature in the step (4) is 120 ^o And C, the time is 24h.

(5) And (5) oxidizing.

Ammonia water solution with ammonia water concentration of 120ml/L and mass fraction of 25 wt%, copper carbonate 40g/L, time of 5min and temperature of 20% ^o C。

Designated as S-3 sample.

Comparative example 1

(2) High temperature chemical reduction copper nanowire seed.

Wherein the high temperature chemistry of step (2) furtherThe original solution is mixed solution of copper acetate and glycerol, 5M anhydrous copper acetate glycerol solution with temperature of 350 DEG C ^o And C, in a non-sealing state, the time is 20min.

(3) And performing hydrothermal treatment to obtain the thorn-shaped copper-based composite material.

The solution used by the water heating in the step (3) is consistent with the solution in the step (2), and the air in the reaction kettle in the step (3) is exhausted by using nitrogen before the step (3) in a closed state.

The hydrothermal temperature in the step (3) is 120 ^o And C, the time is 24h.

(4) And (5) oxidizing.

Wherein the oxidizing solution used in the step (4) is a mixed solution of ammonia water and copper carbonate.

Designated as sample D-1.

And (3) performing mechanical impact test on the ultrasonic oscillation S-3 and the ultrasonic oscillation D-1, wherein the test conditions are as follows: the copper-based composite material was placed in a beaker filled with petroleum ether, and after sealing, the copper-based composite material was subjected to shaking impact in a 40 KHz/100 w ultrasonic cleaner for 60 minutes, the sample was taken out, the weight loss was measured after drying, the mass loss of S-3 was 0.27wt.%, and the mass loss of D-1 was 3.89wt.%, whereby the effect of the preparation of the porous layer of step 2 on the life of the electrode bonding strength could be clearly obtained.

Electrocatalytic reduction CO2 Performance test

An H-type double-air-chamber electrochemical cell is selected in the carbon dioxide reduction reactor device, a copper-based composite material is used as a working electrode, a Pt sheet is used as a counter electrode, an Ag/AgCl electrode is used as a reference electrode, a three-electrode system is formed, a Nafion membrane is used as a diaphragm between the working electrode and the counter electrode/reference electrode, only protons are allowed to pass through, gas communication is blocked, the reaction temperature is normal temperature and normal pressure, and CO is carried out ₂ Before the reduction reaction, CO with high purity (99.99%) is used ₂ Continuously bubbling and cleaning the electrolyte for 30 minutes at the flow rate of 20ml/min to remove other gases in the electrolyte so as to reach CO ₂ Saturated, at-1.8V vs Ag/AgCl electrolysis voltage, 4The product analysis was performed at various moles of potassium bromide for 0min electrolysis time, as shown in table 1 below.

Table 1 product distribution and selectivity at different KBr concentrations.

From Table 1 above, it can be seen that the copper-based composite of the present application has the best selectivity to ethylene and the highest Faraday efficiency.

Table 2 table of faraday efficiencies of copper-based composites at different voltages.

The Faraday efficiency of S-3 ethylene was tested at different voltage ratings of 2.5MKBr, as shown in Table 2, with increasing voltage, FE increased slowly and then decreased rapidly, reaching a peak at-1.8V with an FE value of 64.1%.

Table 3 table CO conversion of copper matrix composites at different times.

As can be seen from the table above, the conversion rate of the copper-based composite material is obviously improved along with time, namely the copper-based composite material has excellent stability and carbon deposition resistance.

The foregoing description of the preferred embodiments of the application is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the application.

Claims

1. The application of the composite material is that the composite material is a copper-based composite material, and is applied to electrocatalytic reduction of CO ₂ The copper-based composite material is characterized by being prepared by the following steps:

(1) Pretreating the copper-based alloy;

(2) Taking copper-containing solution as electrolyte, taking copper-based alloy as cathode, and carrying out electrochemical deposition reduction under extremely high negative bias;

(3) Chemically reducing copper nanowire seed crystals at a high temperature;

(4) Carrying out hydrothermal treatment to obtain a thorn-shaped copper-based composite material;

(5) Oxidizing;

wherein the pretreatment in the step (1) is polishing and inorganic degreasing;

wherein the copper-containing electrolyte in the step (2) comprises 140-150g/L CuSO ₄ ^. 5H ₂ O；30-35g/L H ₂ SO ₄ ；40-45g/L Cl ^- The method comprises the steps of carrying out a first treatment on the surface of the 0.5-1g/L APEO; electrolytic parameters: the temperature is 25-30 ℃; direct-current constant voltage-13V for 5s-10s, wherein the anode is an inert electrode or pure copper, and the copper-containing electrolyte comprises the following components: the method comprises the steps of carrying out a first treatment on the surface of the

Wherein the solution used in the high-temperature chemical reduction in the step (3) is 3-5M glycerol solution of anhydrous copper acetate, the temperature is 300-350 ℃, and the time is 15-20min in a non-closed state;

wherein the solution used in the hydrothermal method in the step (4) is consistent with the solution in the step (3), the hydrothermal temperature is 110-120 ℃ in a closed state, the time is 12-24h,

wherein the oxidizing solution used in the step (5) is a mixed solution of ammonia water and copper carbonate,

2. Use of a composite material according to claim 1, wherein the copper-based alloy is a copper-nickel-white copper alloy, in the shape of a rod or a plate.

3. Use of a composite material according to claim 1, characterized in that the sanding is: sanding was performed using 200#, 600#, 1200# sandpaper in sequence.

4. A composite material as claimed in claim 1The application of the material is characterized in that the degreasing is 15g/L Na ₂ CO ₃ 、 10g/L Na ₃ PO ₄ ^. 12H ₂ O、10 g/L Na ₂ SiO ₃ The temperature was 50℃for 2min.

5. The use of a composite material according to claim 1, wherein the reaction vessels of step (3) and step (4) are stainless steel unlined hydrothermal reaction vessels, and nitrogen is used to evacuate the reaction vessels of step (3) prior to step (4).

6. Use of a composite material according to claim 1, characterized in that the concentration of ammonia in step (5) is 100-120ml/L of an ammonia solution with a mass fraction of 25wt.%, 40g/L of copper carbonate for 3-5min at a temperature of 15-20 ℃.