CN111463018B - Titanium tricarboxide/molybdenum disulfide composite film and preparation method and application thereof - Google Patents

Abstract

The present invention provides a Ti₃C₂/MoS₂A composite film and a preparation method and application thereof relate to the technical field of electric energy storage. The preparation method provided by the invention comprises the following steps: MoS by using rosin amine aqueous solution₂Performing electrostatic adsorption treatment on the powder to obtain rosin amine modified MoS₂An aqueous solution of (a); modifying the rosin amine into MoS₂Aqueous solution of (2) and Ti₃C₂Mixing the powders, performing electrostatic assembly, sequentially performing suction filtration and drying to obtain Ti₃C₂/MoS₂And (3) compounding the film. The preparation method provided by the invention can effectively solve the problem of Ti in the prior art₃C₂The technical problem of aggregation and stacking existing between sheets, and increase of Ti₃C₂/MoS₂Electrochemical and mechanical properties of the composite film.

Description

Titanium tricarboxide/molybdenum disulfide composite film and preparation method and application thereof

Technical Field

The invention relates to the technical field of electric energy storage, in particular to Ti₃C₂/MoS₂A composite film and a preparation method and application thereof.

Background

Supercapacitors are of interest because of their ultra-high power density, long cycle life and wide operating temperature. They are widely used in electric vehicles, portable electronic devices, memory backup devices, large industrial devices, and renewable energy power plans. Supercapacitors can be divided into two categories, Electric Double Layer Capacitors (EDLCs) and pseudocapacitors, depending on the nature of the charge storage mechanism. EDLCs consist of carbonaceous materials, such as Activated Carbon (AC), Carbon Nanotubes (CNTs), or graphene, and charge storage occurs at the electrode/electrolyte interface. The pseudocapacitive electrode is a flexible electrode, and the charge storage of the pseudocapacitive electrode depends on the intercalation process or the reversible redox reaction of an active material. It is reported that pseudocapacitive electrodes have a stronger specific capacitance and a higher energy density than EDLCs. Therefore, the development of pseudo-capacitive flexible electrode materials is needed.

At present, the preparation methods of pseudocapacitive flexible electrodes are various, and the preparation of the filter membrane-based self-supporting carbon (carbon nano tube and graphene) flexible electrode by adopting a vacuum filtration method is one of effective methods. The flexible filter membrane not only can provide a supporting function for the active substances, but also can provide excellent mechanical properties for the super capacitor. However, binders and other additives are often added to the filtrate, which has a great influence on the electrode capacity. Therefore, it is important to prepare a binder-free electrode material.

In recent years, two-dimensional carbon materials have proven to be excellent flexible electrode materials for supercapacitors, among which two-dimensional layered Ti₃C₂The material has good hydrophilicity, high conductivity, adjustable structure, good chemical stability and excellent charge storage capacity, so that the material has very wide application prospect in the aspect of preparing binderless electrodes. However, it was found that Ti₃C₂The hydrogen bonds between the sheets are strong, which causes the aggregation and stacking between the sheets, thereby greatly reducing the transmission efficiency of the electrolyte and seriously limiting Ti₃C₂The electrochemical properties of the sheet play a role.

Disclosure of Invention

In view of the above, the present invention aims to provide a Ti₃C₂/MoS₂The preparation method provided by the invention can effectively solve the problem of Ti in the prior art₃C₂The technical problem of aggregation and stacking between sheets.

In order to achieve the above purpose, the invention provides the following technical scheme:

the invention provides a Ti₃C₂/MoS₂The preparation method of the composite film comprises the following steps:

MoS by using rosin amine aqueous solution₂Performing electrostatic adsorption treatment on the powder to obtain rosin amine modified MoS₂An aqueous solution of (a);

modifying the rosin amine into MoS₂Aqueous solution of (2) and Ti₃C₂Mixing the powders, electrostatic assembling, vacuum filtering, and dryingTo obtain Ti₃C₂/MoS₂And (3) compounding the film.

Preferably, the MoS₂The mass ratio of the powder to the rosin amine in the rosin amine aqueous solution is 1-2: 1 to 5.

Preferably, the mass concentration of the rosin amine aqueous solution is 1%.

Preferably, the Ti₃C₂MoS modified with powder and rosin amine₂The mass ratio of (1-10) to (10-1).

Preferably, the Ti₃C₂The particle size of the powder was 8000 mesh.

Preferably, the material of the filter membrane for suction filtration comprises nylon, polypropylene, polyvinylidene fluoride or polytetrafluoroethylene.

Preferably, the pore diameter of the filter membrane for suction filtration is 0.45 μm.

The invention also provides Ti prepared by the preparation method of the technical scheme₃C₂/MoS₂Composite film of Ti₃C₂And rosin amine modified MoS₂Said Ti₃C₂And rosin amine modified MoS₂The mass ratio of (1-10) to (10-1), the Ti₃C₂/MoS₂The thickness of the composite film was 10 μm.

The invention also provides the Ti in the technical scheme₃C₂/MoS₂The application of the composite film in the preparation of the electrode of the super capacitor.

Preferably, the electrolyte of the supercapacitor electrode is Li₂SO₄And the molar concentration of the electrolyte is 1 mol/L.

The invention provides a Ti₃C₂/MoS₂The preparation method of the composite film comprises the following steps: MoS by using rosin amine aqueous solution₂Performing electrostatic adsorption treatment on the powder to obtain rosin amine modified MoS₂An aqueous solution of (a); modifying the rosin amine into MoS₂Aqueous solution of (2) and Ti₃C₂Mixing the powders, performing electrostatic assembly, sequentially performing suction filtration and drying to obtain Ti₃C₂/MoS₂And (3) compounding the film. In the inventionIn the aqueous solution of rosin amine, the Zeta potential is positive, MoS₂The Zeta potential of the powder in the aqueous solution is negative, and the invention utilizes the aqueous solution of the rosin amine to MoS₂The powder is subjected to electrostatic adsorption treatment, and the rosin amine is adsorbed on MoS₂Surface of powder, to MoS₂Modifying to obtain modified MoS₂Zeta potential in aqueous solution is positive and MoS is increased₂Electrostatic assembly capability. And Ti₃C₂Zeta potential of the powder in aqueous solution is negative, and the invention modifies the rosin amine into MoS₂With Ti₃C₂Mixing the powders, performing electrostatic assembly, and assembling into Ti₃C₂Modified MoS with rosin amine inserted between layers₂Destruction of Ti₃C₂Hydrogen bonding between the sheets to prevent Ti₃C₂Aggregation and stacking between sheets to form Ti₃C₂Can fully exert the function, and MoS₂Also has good electrochemical performance and can effectively improve Ti₃C₂/MoS₂Electrochemical performance of the composite film. The Ti is obtained by suction filtration₃C₂/MoS₂Composite film capable of effectively increasing Ti₃C₂/MoS₂Mechanical properties of the composite film. Therefore, the preparation method provided by the invention can effectively solve the problem of Ti in the prior art₃C₂The technical problem of aggregation and stacking between sheets.

The preparation method provided by the invention is simple, efficient and low in cost, does not add a binder or other additives, and is environment-friendly.

The invention is to mix Ti₃C₂/MoS₂The composite film is used for preparing the electrode of the super capacitor, and can effectively improve the specific capacitance and tensile strength of the electrode.

Drawings

FIG. 1 is Ti₃C₂Scanning electron microscope photographs of (a);

FIG. 2 shows Ti obtained in example 1₃C₂/MoS₂Scanning electron microscope photographs of the composite films;

FIG. 3 is Ti₃C₂Modified MoS with rosin amine₂Zeta potential in water, and Ti obtained in example 1₃C₂/MoS₂Zeta potential of the composite film;

FIG. 4 shows Ti obtained in example 2₃C₂/MoS₂A folded optical pattern of the composite film;

FIG. 5 is a CV diagram of the capacitor electrode prepared in example 2 under different scanning speed conditions;

FIG. 6 is a CV diagram of the capacitor electrode prepared in example 2 under different current density conditions;

FIG. 7 is a graph showing the area specific capacity of the capacitor electrodes obtained in examples 1 to 6 and comparative example.

Detailed Description

The invention provides a Ti₃C₂/MoS₂The preparation method of the composite film comprises the following steps:

MoS by using rosin amine aqueous solution₂Performing electrostatic adsorption treatment on the powder to obtain rosin amine modified MoS₂An aqueous solution of (a);

modifying the rosin amine into MoS₂Aqueous solution of (2) and Ti₃C₂Mixing the powders, performing electrostatic assembly, sequentially performing suction filtration and drying to obtain Ti₃C₂/MoS₂And (3) compounding the film.

In the present invention, the raw materials used are all commercial products conventional in the art unless otherwise specified.

The invention utilizes the rosin amine aqueous solution to the MoS₂Performing electrostatic adsorption treatment on the powder to obtain rosin amine modified MoS₂An aqueous solution of (a).

In the invention, the mass concentration of the rosin amine in the rosin amine aqueous solution is preferably 1%; the source of rosin amine in the rosin amine aqueous solution is preferably rosin amine hydrochloride, and further preferably comprises rosin amine hydrochloride and/or rosin amine hydrobromide. In the present invention, the MoS₂The mass ratio of the powder to the rosin amine in the rosin amine aqueous solution is preferably 1-2: 1 to 5, and more preferably 1.5 to 1.7: 2 to 3. In the present invention, the MoS₂The particle size of the powder is preferably8000 meshes.

In the invention, the electrostatic adsorption treatment is preferably carried out under an ultrasonic condition, and the power of the ultrasonic treatment is preferably 120-1000W. In the invention, the time of the electrostatic adsorption treatment is preferably 6-8 h. In the present invention, the Zeta potential of the rosin amine aqueous solution is positive, MoS₂The Zeta potential of the powder in the aqueous solution is negative, and the invention utilizes the aqueous solution of the rosin amine to MoS₂The powder is subjected to electrostatic adsorption treatment, and the rosin amine is adsorbed on MoS₂Surface of powder, to MoS₂Modifying to obtain modified MoS₂Zeta potential in aqueous solution is positive and MoS is increased₂Electrostatic assembly capability.

After the electrostatic adsorption treatment, the invention preferably performs solid-liquid separation on the obtained electrostatic adsorption treatment product to obtain the modified MoS of the rosin amine₂Then, the rosin amine modified MoS₂Mixing with water to obtain the modified MoS of rosin amine₂An aqueous solution. In the present invention, the solid-liquid separation is preferably performed by centrifugation, and the specific operation of the centrifugation is not particularly limited in the present invention, and the centrifugation known to those skilled in the art may be used, and the excess rosin amine is removed by centrifugation in the present invention. In the present invention, the mixing method is not particularly limited, and MoS after modification of rosin amine can be used₂And (4) uniformly dispersing. The invention has no special limitation on the using amount of the water, and can modify the rosin amine into MoS₂And (4) uniformly dispersing.

Obtaining rosin amine modified MoS₂After the aqueous solution is prepared, the invention modifies the rosin amine into MoS₂Aqueous solution of (2) and Ti₃C₂Mixing the powders, performing electrostatic assembly, sequentially performing suction filtration and drying to obtain Ti₃C₂/MoS₂And (3) compounding the film.

In the present invention, the Ti is₃C₂MoS modified with powder and rosin amine₂The mass ratio of (A) to (B) is preferably (1-10): (10-1), more preferably (1-5): (5-1), and still more preferably 1: 2. When said Ti is₃C₂MoS modified with powder and rosin amine₂When the mass ratio of (a) to (b) is too large,Ti₃C₂too high content of Ti may cause₃C₂The lamination is stacked, and the area specific capacitance performance cannot be fully exerted; when said Ti is₃C₂MoS modified with powder and rosin amine₂When the mass ratio of (A) is too small, MoS₂Too high a content of (b) may lower the conductivity, resulting in a severe decrease in area specific capacitance. In the present invention, the Ti is₃C₂The particle size of the powder is preferably 8000 mesh.

In the present invention, the mixing mode is preferably magnetic stirring, and the rotation speed of the magnetic stirring is preferably 3600 revolutions per minute; the magnetic stirring time is preferably 4-6 h. In the present invention, the Ti is₃C₂MoS modified with powder and rosin amine₂Preferably, the electrostatic assembly is performed while mixing. The invention modifies the rosin amine into MoS₂With Ti₃C₂Mixing the powders, performing electrostatic assembly, and assembling into Ti₃C₂Modified MoS with rosin amine inserted between layers₂Destruction of Ti₃C₂Hydrogen bonding between the sheets to prevent Ti₃C₂Aggregation and stacking between sheets to form Ti₃C₂Can fully exert the function, and MoS₂Also has good electrochemical performance and can effectively improve Ti₃C₂/MoS₂Electrochemical performance of the composite film. The Ti is obtained by suction filtration₃C₂/MoS₂Composite film capable of effectively increasing Ti₃C₂/MoS₂Mechanical properties of the composite film.

In the invention, the material of the filter membrane for suction filtration preferably comprises nylon, polypropylene, polyvinylidene fluoride or polytetrafluoroethylene; the pore diameter of the filtration membrane for suction filtration is preferably 0.45. mu.m. The Ti is obtained by suction filtration₃C₂/MoS₂Composite film capable of effectively increasing Ti₃C₂/MoS₂Mechanical properties of the composite film. The suction filtration method is not particularly limited in the present invention, and a suction filtration method known to those skilled in the art may be adopted.

In the present invention, the drying method is preferably natural drying.

The invention also provides Ti prepared by the preparation method of the technical scheme₃C₂/MoS₂A composite film of the Ti₃C₂/MoS₂Ti in composite film₃C₂Modified MoS with rosin amine₂The mass ratio of (1-10) to (10-1) of Ti₃C₂/MoS₂The thickness of the composite film was 10 μm.

The invention also provides the Ti in the technical scheme₃C₂/MoS₂The application of the composite film in the preparation of the electrode of the super capacitor.

In the present invention, the Ti is₃C₂/MoS₂The size of the composite film is preferably 1cm × 2 cm. In the present invention, the electrolyte of the supercapacitor electrode is preferably Li₂SO₄An electrolyte; the molar concentration of the electrolyte of the supercapacitor electrode is preferably 1 mol/L. In the invention, the working system of the supercapacitor electrode is a three-electrode system. The composition of the three-electrode system is not particularly limited in the present invention, and the composition known to those skilled in the art may be used. The preparation method of the supercapacitor electrode is not particularly limited, and the preparation method of the supercapacitor electrode, which is well known to those skilled in the art, can be adopted.

The following examples are given to provide Ti₃C₂/MoS₂The composite films and the methods of preparation and use thereof are described in detail, but they should not be construed as limiting the scope of the invention.

Example 1

1gMoS₂Adding the powder (with the particle size of 8000 meshes) into 100mL of 1% rosin amine aqueous solution, performing electrostatic adsorption treatment for 8h under the condition that the ultrasonic power is 120W, and centrifuging to obtain the modified MoS of rosin amine₂Modifying the obtained rosin amine to obtain MoS₂Dispersing in water to obtain the modified MoS of rosin amine₂An aqueous solution;

mixing Ti₃C₂Powder (particle size 8000 mesh) is added toMoS modified by rosin amine₂In aqueous solution, Ti₃C₂Powder and rosin amine modified MoS₂The mass ratio of Ti to the components is 5:1, the magnetic stirring is carried out for 6 hours, the rotating speed is 3600 r/min, the Ti is obtained by vacuum filtration and film forming on a nylon filter membrane (the aperture is 0.45 mu m) and natural drying after full electrostatic assembly₃C₂/MoS₂And (3) compounding the film.

The obtained Ti₃C₂/MoS₂The composite film is cut into a size of 1cm multiplied by 2cm, and a three-electrode system is adopted to be 1mol/LLI₂SO₄The electrochemical performance and the tensile strength of the electrolyte are tested, the test results are shown in the table 1, and the test method of the tensile strength is a mechanical measurement method for measuring the thickness of GB6672 plastic films and sheets.

FIG. 1 is Ti₃C₂FIG. 2 is a photograph of Ti prepared in example 1 by scanning electron microscope₃C₂/MoS₂Scanning electron microscope photograph of the composite film. As can be seen from FIGS. 1 and 2, the Ti produced by the present invention₃C₂/MoS₂MoS inserted in composite film₂Can destroy Ti₃C₂Hydrogen bonding between the sheets to prevent Ti₃C₂Aggregation and stacking occurs between sheets.

FIG. 3 is Ti₃C₂Modified MoS with rosin amine₂Zeta potential in water, and Ti obtained in example 1₃C₂/MoS₂Zeta potential of the composite film. As can be seen from the figure, the present invention utilizes an aqueous rosin amine solution to MoS₂The powder is subjected to electrostatic adsorption treatment to modify the rosin amine into MoS₂Zeta potential in aqueous solution is positive with Ti₃C₂After the powder is mixed, electrostatic assembly can be carried out, so that the MoS is modified by rosin amine₂Insertion of Ti₃C₂Between the layers.

Example 2

2gMoS₂Adding the powder (with the particle size of 8000 meshes) into 500mL of 1% rosin amine aqueous solution, performing electrostatic adsorption treatment for 8h under the condition that the ultrasonic power is 120W, and centrifuging to obtain the modified MoS of rosin amine₂Modifying the obtained rosin amine to obtain MoS₂Dispersing in water to obtain the modified MoS of rosin amine₂An aqueous solution;

mixing Ti₃C₂Adding powder (particle size of 8000 meshes) into modified MoS of rosin amine₂In aqueous solution, Ti₃C₂Powder and rosin amine modified MoS₂The mass ratio of Ti to the components is 1:2, the magnetic stirring is carried out for 6 hours, the rotating speed is 3600 r/min, the Ti is obtained by vacuum filtration and film forming on a nylon filter membrane (the aperture is 0.45 mu m) and natural drying after full electrostatic assembly₃C₂/MoS₂And (3) compounding the film.

The obtained Ti₃C₂/MoS₂The composite film is cut into a size of 1cm multiplied by 2cm, and a three-electrode system is adopted to be 1mol/LLI₂SO₄The electrochemical performance and the tensile strength of the electrolyte are tested, the test results are shown in the table 1, and the test method of the tensile strength is a mechanical measurement method for measuring the thickness of GB6672 plastic films and sheets.

FIG. 4 shows Ti obtained in example 2₃C₂/MoS₂The folded optical pattern of the composite film, as can be seen, has the ability to be easily folded.

Fig. 5 is a CV graph of the capacitor electrode prepared in example 2 under different scanning speed conditions, and it can be seen from the graph that the capacitor electrode has better electrochemical performance.

Fig. 6 is a CV graph of the capacitor electrode prepared in example 2 under different current density conditions, and it can be seen that the capacitor electrode has better area specific capacity.

Example 3

1.5g of MoS₂Adding the powder (with the particle size of 8000 meshes) into 200mL of 1% rosin amine aqueous solution, performing electrostatic adsorption treatment for 8h under the condition that the ultrasonic power is 120W, and centrifuging to obtain the modified MoS of rosin amine₂Modifying the obtained rosin amine to obtain MoS₂Dispersing in water to obtain the modified MoS of rosin amine₂An aqueous solution;

mixing Ti₃C₂Adding powder (particle size of 8000 meshes) into modified MoS of rosin amine₂In aqueous solution, Ti₃C₂Powder and rosin amine modified MoS₂Mass ratio ofStirring for 6h at 3600 rpm under magnetic force of 10:1, performing electrostatic assembly, vacuum filtering on nylon filter membrane (aperture of 0.45 μm) to obtain film, and naturally drying to obtain Ti₃C₂/MoS₂And (3) compounding the film.

The obtained Ti₃C₂/MoS₂The composite film is cut into a size of 1cm multiplied by 2cm, and a three-electrode system is adopted to be 1mol/LLI₂SO₄The electrochemical performance and the tensile strength of the electrolyte are tested, the test results are shown in the table 1, and the test method of the tensile strength is a mechanical measurement method for measuring the thickness of GB6672 plastic films and sheets.

Example 4

1.5g of MoS₂Adding the powder (with the particle size of 8000 meshes) into 200mL of 1% rosin amine aqueous solution, performing electrostatic adsorption treatment for 8h under the condition that the ultrasonic power is 120W, and centrifuging to obtain the modified MoS of rosin amine₂Modifying the obtained rosin amine to obtain MoS₂Dispersing in water to obtain the modified MoS of rosin amine₂An aqueous solution;

mixing Ti₃C₂Adding powder (particle size of 8000 meshes) into modified MoS of rosin amine₂In aqueous solution, Ti₃C₂Powder and rosin amine modified MoS₂The mass ratio of Ti to the components is 1:10, the magnetic stirring is carried out for 6 hours, the rotating speed is 3600 r/min, the Ti is obtained by vacuum filtration and film forming on a nylon filter membrane (the aperture is 0.45 mu m) and natural drying after full electrostatic assembly₃C₂/MoS₂And (3) compounding the film.

The obtained Ti₃C₂/MoS₂The composite film is cut into a size of 1cm multiplied by 2cm, and a three-electrode system is adopted to be 1mol/LLI₂SO₄The electrochemical performance and the tensile strength of the electrolyte are tested, the test results are shown in the table 1, and the test method of the tensile strength is a mechanical measurement method for measuring the thickness of GB6672 plastic films and sheets.

Example 5

1.5g of MoS₂Adding powder (particle size of 8000 mesh) into 200mL of 1% rosin amine aqueous solution, performing electrostatic adsorption treatment for 8h under the condition of ultrasonic power of 120W, and centrifuging to obtain rosin amine modified productPost sexual MoS₂Modifying the obtained rosin amine to obtain MoS₂Dispersing in water to obtain the modified MoS of rosin amine₂An aqueous solution;

mixing Ti₃C₂Adding powder (particle size of 8000 meshes) into modified MoS of rosin amine₂In aqueous solution, Ti₃C₂Powder and rosin amine modified MoS₂The mass ratio of Ti to the component (A) is 4:3, the magnetic stirring is carried out for 6 hours, the rotating speed is 3600 r/min, the Ti is obtained by vacuum filtration membrane forming and natural drying after full electrostatic assembly on a nylon filter membrane (the aperture is 0.45 mu m)₃C₂/MoS₂And (3) compounding the film.

The obtained Ti₃C₂/MoS₂The composite film is cut into a size of 1cm multiplied by 2cm, and a three-electrode system is adopted to be 1mol/LLI₂SO₄The electrochemical performance and the tensile strength of the electrolyte are tested, the test results are shown in the table 1, and the test method of the tensile strength is a mechanical measurement method for measuring the thickness of GB6672 plastic films and sheets.

Example 6

1.5g of MoS₂Adding the powder (with the particle size of 8000 meshes) into 200mL of 1% rosin amine aqueous solution, performing electrostatic adsorption treatment for 8h under the condition that the ultrasonic power is 120W, and centrifuging to obtain the modified MoS of rosin amine₂Modifying the obtained rosin amine to obtain MoS₂Dispersing in water to obtain the modified MoS of rosin amine₂An aqueous solution;

mixing Ti₃C₂Adding powder (particle size of 8000 meshes) into modified MoS of rosin amine₂In aqueous solution, Ti₃C₂Powder and rosin amine modified MoS₂The mass ratio of Ti to the components is 1:15, the magnetic stirring is carried out for 6 hours, the rotating speed is 3600 r/min, the Ti is obtained by vacuum filtration and film forming on a nylon filter membrane (the aperture is 0.45 mu m) and natural drying after full electrostatic assembly₃C₂/MoS₂And (3) compounding the film.

The obtained Ti₃C₂/MoS₂The composite film is cut into a size of 1cm multiplied by 2cm, and a three-electrode system is adopted to be 1mol/LLI₂SO₄The electrochemical properties and tensile strength were measured in the electrolyte and the results are shown in Table 1The tensile strength is measured mechanically by measuring the thickness of the plastic film and sheet of GB 6672.

Comparative example

Will contain 5g Ti₃C₂Filtering the aqueous solution on a nylon filter membrane (the aperture is 0.45 mu m) to form a membrane and naturally drying to obtain Ti₃C₂A film.

The obtained Ti₃C₂/MoS₂The composite film is cut into a size of 1cm multiplied by 2cm, and a three-electrode system is adopted to be 1mol/LLI₂SO₄The electrochemical performance and the tensile strength of the electrolyte are tested, the test results are shown in the table 1, and the test method of the tensile strength is a mechanical measurement method for measuring the thickness of GB6672 plastic films and sheets.

Table 1 test results of area specific capacity and tensile strength of the capacitor electrodes prepared in examples 1 to 6 and comparative example.

FIG. 7 is a graph showing the area specific capacity of the capacitor electrodes obtained in examples 1 to 6 and comparative example, and analysis of Ti is shown in combination with FIG. 7 and Table 1₃C₂/MoS₂The composite film has a specific Ti₃C₂The area specific capacity and tensile strength of the film are more excellent.

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 (10)

1. Ti₃C₂/MoS₂The preparation method of the composite film is characterized by comprising the following steps:

MoS by using rosin amine aqueous solution₂Performing electrostatic adsorption treatment on the powder to obtain rosin amine modified MoS₂An aqueous solution of (a);

modifying the rosin amine into MoS₂Aqueous solution of (2) and Ti₃C₂Mixing the powders, performing electrostatic assembly, sequentially performing suction filtration and drying to obtain Ti₃C₂/MoS₂And (3) compounding the film.

2. The method of claim 1, wherein the MoS is prepared by a method comprising₂The mass ratio of the powder to the rosin amine in the rosin amine aqueous solution is 1-2: 1 to 5.

3. The production method according to claim 1 or 2, wherein the concentration by mass of the rosin amine aqueous solution is 1%.

4. The method according to claim 1, wherein the Ti is₃C₂Powder and rosin amine modified MoS₂The mass ratio of (1-10) to (10-1).

5. The production method according to claim 1 or 4, wherein the Ti is₃C₂The particle size of the powder was 8000 mesh.

6. The method according to claim 1, wherein the material of the filtration membrane for suction filtration comprises nylon, polypropylene, polyvinylidene fluoride, or polytetrafluoroethylene.

7. The production method according to claim 1 or 6, wherein the pore size of the filtration membrane for suction filtration is 0.45 μm.

8. Ti produced by the production method according to any one of claims 1 to 7₃C₂/MoS₂Composite film of Ti₃C₂And rosin amine modified MoS₂Said Ti₃C₂And rosin amine modified MoS₂The mass ratio of (1-10) to (10-1), the Ti₃C₂/MoS₂The thickness of the composite film was 10 μm.

9. Ti according to claim 8₃C₂/MoS₂The application of the composite film in the preparation of the electrode of the super capacitor.

10. The use according to claim 9, wherein the electrolyte of the supercapacitor electrode is Li₂SO₄And the molar concentration of the electrolyte is 1 mol/L.

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