CN114016079A - Fe-Ni LDH-MoS2NGAs hydrogen evolution material and preparation method and application thereof - Google Patents

Abstract

The invention relates to the technical field of hydrogen energy, in particular to Fe-Ni LDH-MoS₂/NGAs hydrogen evolution material and a preparation method and application thereof. Firstly, uniformly mixing a graphene oxide suspension and ethylenediamine, and then carrying out hydrothermal reaction to obtain NGAs; then sodium molybdate, thioacetamide and water are evenly mixed and pumped into a reaction kettle, NGAs is used as a carrier, and MoS is obtained through hydrothermal reaction₂(ii)/NGAs; uniformly mixing ferric nitrate, nickel nitrate, ammonium fluoride, urea and water, and adding the mixture into MoS₂in/NGAs, the mixture is transferred into a reaction kettle for hydrothermal reaction and dried to obtain Fe‑NiLDH‑MoS₂/NGAs hydrogen evolving materials; the material is applied to electrocatalytic hydrogen evolution reaction. Compared with the prior art, the preparation method has the advantages of low raw material cost, simple preparation mode and good hydrogen and oxygen evolution effects in alkaline solution, and is expected to be oriented to industrial development.

Description

Fe-Ni LDH-MoS2NGAs hydrogen evolution material and preparation method and application thereof

Technical Field

The invention relates to the technical field of hydrogen energy, in particular to Fe-Ni LDH-MoS₂/NGAs hydrogen evolution material and a preparation method and application thereof.

Background

With the increasing exhaustion of fossil fuels, various new energy sources are continuously developed and utilized. The hydrogen energy is used as a renewable secondary energy source, has wide source, high heat value, cleanness and good combustion stability, and is a new generation of energy carrier widely adopted after non-renewable energy sources such as fossil fuel and the like. Chemical water splitting is strongly dependent on mass transport and active centers, however, difficulty in promoting mass transport and exposing enough active centers are the major bottlenecks of the two half-reactions of total water splitting, namely: hydrogen Evolution Reaction (HER) and Oxygen Evolution Reaction (OER). The alkaline electrolysis of water for hydrogen production is the most potential technical means leading to hydrogen economy, but the reaction energy consumption is larger due to the existence of hydrogen evolution and oxygen evolution overpotential in the electrolysis process. In order to reduce energy consumption, it is of great significance to develop a cathode electrode material with low cost and high catalytic activity. The alkaline electrolysis of water for hydrogen production is the most potential technical means leading to hydrogen economy, but the reaction energy consumption is larger due to the existence of hydrogen evolution and oxygen evolution overpotential in the electrolysis process. In order to reduce energy consumption, it is of great significance to develop a cathode electrode material with low cost and high catalytic activity.

In general, high activity HER electrocatalysts require several characteristics: inherently high specific surface area, high conductivity and fast electron transfer pathways, as well as a large number of active sites and fast mass transport pathways (including transport of reaction substrates and diffusion of gaseous products). Although Pt and Ru/Ir based composites are considered the most advanced electrocatalysts for HER and OER, their high cost and scarcity severely hamper large scale applications. Therefore, much research effort has been devoted to developing earth-abundant alternatives with high efficiency and stability.

Disclosure of Invention

In order to overcome the problem of catalytic hydrogen evolution in the prior art, the invention aims to provide Fe-Ni LDH-MoS₂/NGAs hydrogen evolution material and a preparation method and application thereof. The Fe-Ni LDH-MoS₂the/NGAs hydrogen evolution material is used as a catalyst, the synthesis cost is lower than that of most catalysts, and the earth reserves of main elements of Fe and Ni are sufficient. In the metal molybdenum, the 3d orbit is in a half-full state, has strong adsorption effect on hydrogen atoms, and is combined with the graphene oxide aerogel, so that the hydrogen evolution performance of the graphene oxide aerogel is greatly enhanced, the electrochemical performance of the graphene oxide aerogel is improved, and the synthesis method is simple.

The purpose of the invention can be realized by the following technical scheme:

the first purpose of the invention is to provide Fe-Ni LDH-MoS₂The preparation method of the/NGAs hydrogen evolution material comprises the following steps:

(1) uniformly mixing the graphene oxide suspension with ethylenediamine, transferring the mixture to a hydrothermal kettle, and carrying out hydrothermal reaction to obtain NGAs;

(2) mixing sodium molybdate, thioacetamide and water uniformly to obtain a first mixed solution;

(3) adding the first mixed solution obtained in the step (2) into a reaction kettle, taking NGAs obtained in the step (1) as a carrier, and obtaining MoS after hydrothermal reaction₂/NGAs；

(4) Mixing ferric nitrate and nitreUniformly mixing nickel acid, ammonium fluoride, urea and water, and adding the MoS obtained in the step (3)₂In the/NGAs, standing to obtain a second mixed solution;

(5) carrying out hydrothermal reaction on the second mixed solution obtained in the step (4) in a transfer reaction kettle, and drying to obtain Fe-Ni LDH-MoS₂/NGAs hydrogen evolution materials.

In one embodiment of the present invention, in the step (1), the volume ratio of the graphene oxide suspension to the ethylenediamine is 5: 1.

in one embodiment of the present invention, in the step (1), the reaction temperature is 150 ℃ to 200 ℃ and the reaction time is 10 to 15 hours during the hydrothermal reaction.

In one embodiment of the present invention, in step (2), the molar ratio of sodium molybdate to thioacetamide is 3: 4; the dosage ratio of the sodium molybdate to the water is 3 mmol: (150- & lt 250- & gt) mL.

In one embodiment of the present invention, in the step (3), the ratio of the amount of the first mixed solution to the amount of NGAs is 20 mL: 0.01 g.

In one embodiment of the present invention, in the step (3), the reaction temperature is 150-.

In one embodiment of the present invention, in step (4), the amount ratio of iron nitrate, nickel nitrate, ammonium fluoride and urea to water is 2 mmol: 3 mmol: 3 mmol: 1 mmol: 30 ml.

In one embodiment of the present invention, in the step (5), the reaction temperature is 110-150 ℃ and the reaction time is 10-15h during the hydrothermal reaction.

The second purpose of the invention is to provide Fe-Ni LDH-MoS prepared by the method₂/NGAs hydrogen evolution materials.

The third purpose of the invention is to provide the Fe-Ni LDH-MoS₂Application of/NGAs hydrogen evolution material, Fe-Ni LDH-MoS₂the/NGAs hydrogen evolution material is used for electrocatalytic hydrogen and oxygen evolution reaction.

In one embodiment of the invention, Fe-Ni LDH-MoS is added₂the/NGAs hydrogen evolution material is uniformly mixed with Nafion solution, dripped on a glassy carbon electrode, and driedThen obtaining the hydrogen evolution glassy carbon electrode which is used as a working electrode in the electrocatalytic hydrogen evolution reaction.

In one embodiment of the invention, Fe-Ni LDH-MoS₂The application method of the NGAs hydrogen evolution material for electrocatalytic hydrogen and oxygen evolution reaction specifically comprises the following steps:

(1) weighing 5mg of Fe-Ni LDH-MoS₂Dissolving the/NGAs hydrogen evolution material in 30 mu L of prepared 0.5 wt% of a Nation solution, uniformly dispersing for half an hour under ultrasonic, sucking 12-18 mu L of the solution on a glassy carbon electrode, and naturally airing to obtain the hydrogen evolution glassy carbon electrode;

(2) preparing 1.0M potassium hydroxide solution as electrocatalytic electrolyte, introducing nitrogen to remove air, cleaning the surface of the glassy carbon electrode by using 1.0M potassium hydroxide solution, connecting the hydrogen evolution glassy carbon electrode, the Ag/AgCl electrode and the graphite electrode to an electrochemical workstation, and carrying out electrocatalytic hydrogen evolution reaction in the electrolyte.

In one embodiment of the present invention, the purpose of the hydrothermal reaction is: the reaction is promoted to be carried out in a high-temperature and high-pressure environment, and the obtained NGAs are uniform, free of agglomeration, good in crystal form and MoS₂Can be better loaded on the graphene oxide aerogel. The secondary hydrothermal reaction causes Fe-Ni LDH to be loaded on MoS₂the/NGAs surface is tightly combined, and is more beneficial to hydrogen evolution and oxygen evolution. Wherein MoS₂As the active site for hydrogen evolution, Fe-Ni LDH is taken as the active site for oxygen evolution, and the two sites supplement each other to further promote the complete decomposition of water.

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

(1) in the present invention, the graphene oxide aerogel is generally obtained by supercritical carbon dioxide drying or freeze drying of a wet gel to replace a solvent with air, and is a three-dimensional (3D) porous solid material including high porosity, excellent mass transfer capacity, and low bulk density and dielectric constant. The graphene oxide aerogel serving as one of graphene-based porous materials not only can inherit the excellent internal performance of graphene, but also has a large specific surface area, and the graphene oxide aerogel has high porosity and an interconnected network structure and can improve the material performance.

(2) Fe-Ni LDH-MoS prepared by the invention₂The graphene oxide aerogel in the/NGAs hydrogen evolution material has a three-dimensional framework structure, and the re-stacking of graphene sheets can be effectively inhibited, so that the large specific surface area of graphene can be kept, and a plurality of accessible active sites can be exposed; the abundant porous structure can store electrolyte and provide more mass transfer channels, thereby shortening the mass transfer distance and accelerating the mass transfer; highly crystalline and interconnected graphene sheets can provide more electron transport paths, facilitating the conduction of electrons; the surface of the graphene oxide aerogel is easy to modify, and the graphene is endowed with a catalytic function.

(3) The invention relates to Fe-Ni LDH-MoS₂The preparation method of the/NGAs hydrogen evolution material has low raw material cost and simple preparation mode, and the prepared Fe-Ni LDH-MoS₂The NGAs hydrogen evolution material has good hydrogen evolution effect, and the introduction of non-noble metal elements ensures that the material has good stability. The water is electrolyzed in the alkaline medium, and the hydrogen evolution effect is good.

Detailed Description

The invention provides Fe-Ni LDH-MoS₂The preparation method of the/NGAs hydrogen evolution material comprises the following steps:

(1) uniformly mixing the graphene oxide suspension with ethylenediamine, transferring the mixture to a hydrothermal kettle, and carrying out hydrothermal reaction to obtain NGAs;

(2) mixing sodium molybdate, thioacetamide and water uniformly to obtain a first mixed solution;

(3) adding the first mixed solution obtained in the step (2) into a reaction kettle, taking NGAs obtained in the step (1) as a carrier, and obtaining MoS after hydrothermal reaction₂/NGAs；

(4) Uniformly mixing ferric nitrate, nickel nitrate, ammonium fluoride, urea and water, and adding the MoS obtained in the step (3)₂In the/NGAs, standing to obtain a second mixed solution;

(5) carrying out hydrothermal reaction on the second mixed solution obtained in the step (4) in a transfer reaction kettle, and drying to obtain Fe-Ni LDH-MoS₂/NGAs hydrogen evolution materials.

In one embodiment of the present invention, in the step (1), the volume ratio of the graphene oxide suspension to the ethylenediamine is 5: 1.

in one embodiment of the present invention, in the step (1), the reaction temperature is 150 ℃ to 200 ℃ and the reaction time is 10 to 15 hours during the hydrothermal reaction.

In one embodiment of the present invention, in step (2), the molar ratio of sodium molybdate to thioacetamide is 3: 4; the dosage ratio of the sodium molybdate to the water is 3 mmol: (150- > 250) mL.

In one embodiment of the present invention, in the step (3), the ratio of the amount of the first mixed solution to the amount of NGAs is 20 mL: 0.01 g.

In one embodiment of the present invention, in the step (3), the reaction temperature is 150-.

In one embodiment of the present invention, in step (4), the amount ratio of iron nitrate, nickel nitrate, ammonium fluoride and urea to water is 2 mmol: 3 mmol: 3 mmol: 1 mmol: 30 ml.

In one embodiment of the present invention, in the step (5), the reaction temperature is 110-150 ℃ and the reaction time is 10-15h during the hydrothermal reaction.

The invention provides Fe-Ni LDH-MoS prepared by the method₂/NGAs hydrogen evolution materials.

The invention provides the Fe-Ni LDH-MoS₂Application of/NGAs hydrogen evolution material, Fe-Ni LDH-MoS₂the/NGAs hydrogen evolution material is used for electrocatalytic hydrogen and oxygen evolution reaction.

In one embodiment of the invention, Fe-Ni LDH-MoS is added₂the/NGAs hydrogen evolution material is uniformly mixed with Nafion solution, then is dripped on a glassy carbon electrode, and is dried to obtain the hydrogen evolution glassy carbon electrode which is used as a working electrode in the electrocatalytic hydrogen evolution reaction.

In one embodiment of the invention, Fe-Ni LDH-MoS₂The application method of the NGAs hydrogen evolution material for electrocatalytic hydrogen and oxygen evolution reaction specifically comprises the following steps:

(1) weighing 5mg of Fe-Ni LDH-MoS₂Dissolving the/NGAs hydrogen evolution material in 30 mu L of prepared 0.5 wt% of Nation solution, uniformly dispersing for half an hour under ultrasound, and absorbing 12-Putting 18 mu L of the solution on a glassy carbon electrode, and naturally airing to obtain a hydrogen evolution glassy carbon electrode;

(2) preparing 1.0M potassium hydroxide solution as electrocatalytic electrolyte, introducing nitrogen to remove air, cleaning the surface of the glassy carbon electrode by using 1.0M potassium hydroxide solution, connecting the hydrogen evolution glassy carbon electrode, the Ag/AgCl electrode and the graphite electrode to an electrochemical workstation, and carrying out electrocatalytic hydrogen evolution reaction in the electrolyte.

In one embodiment of the present invention, the purpose of the hydrothermal reaction is: the reaction is promoted to be carried out in a high-temperature and high-pressure environment, and the obtained NGAs are uniform, free of agglomeration, good in crystal form and MoS₂Can be better loaded on the graphene oxide aerogel. The secondary hydrothermal reaction causes Fe-Ni LDH to be loaded on MoS₂the/NGAs surface is tightly combined, and is more beneficial to hydrogen evolution and oxygen evolution. Wherein MoS₂As the active site for hydrogen evolution, Fe-Ni LDH is taken as the active site for oxygen evolution, and the two sites supplement each other to further promote the complete decomposition of water.

The present invention will be described in detail with reference to specific examples.

The raw materials used in the examples of the present invention are commercially available unless otherwise specified.

Example 1

This example provides a Fe-Ni LDH-MoS₂Preparation method of NGAs hydrogen evolution material.

Adding 2ml of ethylenediamine into 10ml of graphene oxide suspension, stirring, and then transferring to a hydrothermal kettle for reaction at 180 ℃ for 12h to obtain NGAs. Dissolving 0.3mmol of sodium molybdate and 0.4mmol of thioacetamide in 20mL of deionized water, and carrying out ultrasonic treatment in an ultrasonic oscillator for 2 hours until the mixture is stirred and dissolved to obtain a first mixed solution. After no solid particles exist in the solution, NGAs is put into the first mixed solution, stands for 30 minutes and is transferred to a high-pressure reaction kettle, and then is heated for 24 hours under the temperature of 200 ℃. Remove the MoS₂/NGAs. Adding 0.2mmol of ferric nitrate, 0.3mmol of nickel nitrate, 0.3mmol of ammonium fluoride and 0.1mmol of urea into 30ml of deionized water, stirring for 30 minutes, and adding MoS₂/NGAs stands for 20 minutes to obtain a second mixed solution; then transferring the mixture into a hydrothermal kettle for reaction at 120 ℃ for 12h, cooling the mixture, taking out the mixture for washing at 60 DEG CVacuum drying overnight to finally obtain Fe-Ni LDH-MoS₂/NGAs hydrogen evolution materials.

Example 2

The Fe-Ni LDH-MoS of example 1 was added₂Grinding the/NGAs hydrogen evolution material, grinding the surface of the glassy carbon electrode by using 0.05 mu m of alumina, removing a residual sample, washing by using ethanol and deionized water, and airing.

(1) Nation solution was made up to 0.5 wt% with anhydrous methanol. Weighing 5mg of Fe-Ni LDH-MoS₂the/NGAs hydrogen evolution material is dissolved in 30 mu L of prepared Nation solution and evenly dispersed for half an hour under ultrasound. Then sucking 12 mu L of the solution on a glassy carbon electrode, and naturally airing to obtain the hydrogen evolution glassy carbon electrode.

(2) Preparing 1.0M potassium hydroxide solution as an electrocatalytic electrolyte, introducing nitrogen to drive away air, cleaning the electrode surface of the hydrogen evolution glassy carbon electrode by using the 1.0M potassium hydroxide solution, connecting the hydrogen evolution glassy carbon electrode, the Ag/AgCl electrode and the graphite electrode to an electrochemical workstation, and measuring the electrocatalytic hydrogen evolution performance of the electrode material in the electrolyte.

Example 3

This example provides a Fe-Ni LDH-MoS₂Preparation method of NGAs hydrogen evolution material.

Adding 2ml of ethylenediamine into 10ml of graphene oxide suspension, stirring, and then transferring to a hydrothermal kettle for reaction at 150 ℃ for 10h to obtain NGAs. Dissolving 0.3mmol of sodium molybdate and 0.4mmol of thioacetamide in 25mL of deionized water, and carrying out ultrasonic treatment in an ultrasonic oscillator for 2 hours until the mixture is stirred and dissolved to obtain a first mixed solution. And after no solid particles exist in the solution, NGAs is put into the first mixed solution, stands for 30 minutes and is transferred to a high-pressure reaction kettle, and then is heated for 20 hours at 150 ℃. Remove the MoS₂/NGAs. Adding 0.2mmol of ferric nitrate, 0.3mmol of nickel nitrate, 0.3mmol of ammonium fluoride and 0.1mmol of urea into 30ml of deionized water, stirring for 30 minutes, and adding MoS₂/NGAs stands for 20 minutes to obtain a second mixed solution; then transferring the mixture into a hydrothermal kettle for reaction at 110 ℃ for 10h, cooling, taking out and washing, and carrying out vacuum drying at 60 ℃ overnight to finally obtain Fe-Ni LDH-MoS₂/NGAs hydrogen evolution materials.

Example 4

The Fe-Ni LDH-MoS of example 3 was added₂Grinding the/NGAs hydrogen evolution material, grinding the surface of the glassy carbon electrode by using 0.05 mu m of alumina, removing a residual sample, washing by using ethanol and deionized water, and airing.

(1) 0.5 wt% of Nation solution was prepared with anhydrous methanol. Weighing 5mg of Fe-Ni LDH-MoS₂the/NGAs hydrogen evolution material is dissolved in 30 mu L of prepared Nation solution and is homogenized under ultrasound for half an hour. Then sucking 12 mu L of the solution on a glassy carbon electrode, and naturally airing to obtain the hydrogen evolution glassy carbon electrode.

(2) Preparing 1.0M potassium hydroxide solution as an electrocatalytic electrolyte, introducing nitrogen to drive away air, cleaning the electrode surface of the hydrogen evolution glassy carbon electrode by using the 1.0M potassium hydroxide solution, connecting the hydrogen evolution glassy carbon electrode, the Ag/AgCl electrode and the graphite electrode to an electrochemical workstation, and measuring the electrocatalytic hydrogen evolution performance of the electrode material in the electrolyte.

Example 5

This example provides a Fe-Ni LDH-MoS₂Preparation method of NGAs hydrogen evolution material.

Adding 2ml of ethylenediamine into 10ml of graphene oxide suspension, stirring, and then transferring to a hydrothermal kettle for reaction at 200 ℃ for 15h to obtain NGAs. Dissolving 0.3mmol of sodium molybdate and 0.4mmol of thioacetamide in 15mL of deionized water, and carrying out ultrasonic treatment in an ultrasonic oscillator for 2 hours until the mixture is stirred and dissolved to obtain a first mixed solution. And after no solid particles exist in the solution, NGAs is put into the first mixed solution, stands for 30 minutes and is transferred to a high-pressure reaction kettle, and then is heated for 22 hours at 180 ℃. Remove the MoS₂/NGAs. Adding 0.2mmol of ferric nitrate, 0.3mmol of nickel nitrate, 0.3mmol of ammonium fluoride and 0.1mmol of urea into 30ml of deionized water, stirring for 30 minutes, and adding MoS₂/NGAs stands for 20 minutes to obtain a second mixed solution; then transferring the mixture into a hydrothermal kettle to react for 15h at the temperature of 150 ℃, cooling the mixture, taking out the mixture to wash the mixture, and drying the mixture overnight in vacuum at the temperature of 60 ℃ to finally obtain Fe-Ni LDH-MoS₂/NGAs hydrogen evolution materials.

Example 6

The Fe-Ni LDH-MoS of example 5 was added₂Research on/NGAs hydrogen evolution materialGrinding, namely grinding the surface of the glassy carbon electrode by using 0.05 mu m of alumina, removing a residual sample, washing by using ethanol and deionized water, and airing.

(1) 0.5 wt% of Nation solution was prepared with anhydrous methanol. Weighing 5mg of Fe-Ni LDH-MoS₂the/NGAs hydrogen evolution material is dissolved in 30 mu L of prepared Nation solution and evenly dispersed for half an hour under ultrasound. Then sucking 12 mu L of the solution on a glassy carbon electrode, and naturally airing to obtain the hydrogen evolution glassy carbon electrode.

(2) Preparing 1.0M potassium hydroxide solution as an electrocatalytic electrolyte, introducing nitrogen to drive away air, cleaning the electrode surface of the hydrogen evolution glassy carbon electrode by using the 1.0M potassium hydroxide solution, connecting the hydrogen evolution glassy carbon electrode, the Ag/AgCl electrode and the graphite electrode to an electrochemical workstation, and measuring the electrocatalytic hydrogen evolution performance of the electrode material in the electrolyte.

Example 7

This example provides a Fe-Ni LDH-MoS₂Preparation method of NGAs hydrogen evolution material.

Adding 2ml of ethylenediamine into 10ml of graphene oxide suspension, stirring, and then transferring to a hydrothermal kettle for reaction at 150 ℃ for 10h to obtain NGAs. Dissolving 0.3mmol of sodium molybdate and 0.4mmol of thioacetamide in 20mL of deionized water, and carrying out ultrasonic treatment in an ultrasonic oscillator for 2 hours until the mixture is stirred and dissolved to obtain a first mixed solution. And after no solid particles exist in the solution, NGAs is put into the first mixed solution, stands for 30 minutes and is transferred to a high-pressure reaction kettle, and then is heated for 20 hours at 150 ℃. Remove the MoS₂/NGAs. Adding 0.2mmol of ferric nitrate, 0.3mmol of nickel nitrate, 0.3mmol of ammonium fluoride and 0.1mmol of urea into 30ml of deionized water, stirring for 30 minutes, and adding MoS₂/NGAs stands for 20 minutes to obtain a second mixed solution; then transferring the mixture into a hydrothermal kettle for reaction at 110 ℃ for 10h, cooling, taking out and washing, and carrying out vacuum drying at 60 ℃ overnight to finally obtain Fe-Ni LDH-MoS₂/NGAs hydrogen evolution materials.

Example 8

The Fe-Ni LDH-MoS of example 7 was added₂Grinding the/NGAs hydrogen evolution material, grinding the surface of the glassy carbon electrode by using 0.05 mu m of aluminum oxide, removing the residual sample, and using ethanol and deionized waterAnd (5) washing and drying.

(1) 0.5 wt% of Nation solution was prepared with anhydrous methanol. Weighing 5mg of Fe-Ni LDH-MoS₂the/NGAs hydrogen evolution material is dissolved in 30 mu L of prepared Nation solution and is homogenized under ultrasound for half an hour. Then sucking 12 mu L of the solution on a glassy carbon electrode, and naturally airing to obtain the hydrogen evolution glassy carbon electrode.

(2) Preparing 1.0M potassium hydroxide solution as an electrocatalytic electrolyte, introducing nitrogen to drive away air, cleaning the electrode surface of the hydrogen evolution glassy carbon electrode by using the 1.0M potassium hydroxide solution, connecting the hydrogen evolution glassy carbon electrode, the Ag/AgCl electrode and the graphite electrode to an electrochemical workstation, and measuring the electrocatalytic hydrogen evolution performance of the electrode material in the electrolyte.

Example 9

This example provides a Fe-Ni LDH-MoS₂Preparation method of NGAs hydrogen evolution material.

Adding 2ml of ethylenediamine into 10ml of graphene oxide suspension, stirring, and then transferring to a hydrothermal kettle for reaction at 150 ℃ for 10h to obtain NGAs. Dissolving 0.3mmol of sodium molybdate and 0.4mmol of thioacetamide in 20mL of deionized water, and carrying out ultrasonic treatment in an ultrasonic oscillator for 2 hours until the mixture is stirred and dissolved to obtain a first mixed solution. And after no solid particles exist in the solution, NGAs is put into the first mixed solution, stands for 30 minutes and is transferred to a high-pressure reaction kettle, and then is heated for 20 hours at 150 ℃. Remove the MoS₂/NGAs. Adding 0.2mmol of ferric nitrate, 0.3mmol of nickel nitrate, 0.3mmol of ammonium fluoride and 0.1mmol of urea into 30ml of deionized water, stirring for 30 minutes, and adding MoS₂/NGAs stands for 20 minutes to obtain a second mixed solution; then transferring the mixture into a hydrothermal kettle to react for 12 hours at 120 ℃, cooling the mixture, taking out the mixture to wash the mixture, and drying the mixture overnight in vacuum at 60 ℃ to finally obtain Fe-Ni LDH-MoS₂/NGAs hydrogen evolution materials.

Example 10

The Fe-Ni LDH-MoS of example 9 was added₂Grinding the/NGAs hydrogen evolution material, grinding the surface of the glassy carbon electrode by using 0.05 mu m of alumina, removing a residual sample, washing by using ethanol and deionized water, and airing.

(1) 0.5 wt% of Nation solution was prepared with anhydrous methanol. Weighing 5mg of Fe-Ni LDH-MoS₂the/NGAs hydrogen evolution material is dissolved in 30 mu L of prepared Nation solution and is homogenized under ultrasound for half an hour. Then sucking 12 mu L of the solution on a glassy carbon electrode, and naturally airing to obtain the hydrogen evolution glassy carbon electrode.

(2) Preparing 1.0M potassium hydroxide solution as an electrocatalytic electrolyte, introducing nitrogen to drive away air, cleaning the electrode surface of the hydrogen evolution glassy carbon electrode by using the 1.0M potassium hydroxide solution, connecting the hydrogen evolution glassy carbon electrode, the Ag/AgCl electrode and the graphite electrode to an electrochemical workstation, and measuring the electrocatalytic hydrogen evolution performance of the electrode material in the electrolyte.

The embodiments described above are described to facilitate an understanding and use of the invention by those skilled in the art. It will be readily apparent to those skilled in the art that various modifications to these embodiments may be made, and the generic principles described herein may be applied to other embodiments without the use of the inventive faculty. Therefore, the present invention is not limited to the above embodiments, and those skilled in the art should make improvements and modifications within the scope of the present invention based on the disclosure of the present invention.

Claims (10)

1. Fe-Ni LDH-MoS₂The preparation method of the/NGAs hydrogen evolution material is characterized by comprising the following steps:

(1) uniformly mixing the graphene oxide suspension with ethylenediamine, transferring the mixture to a hydrothermal kettle, and carrying out hydrothermal reaction to obtain NGAs;

(2) mixing sodium molybdate, thioacetamide and water uniformly to obtain a first mixed solution;

(3) adding the first mixed solution obtained in the step (2) into a reaction kettle, taking NGAs obtained in the step (1) as a carrier, and obtaining MoS after hydrothermal reaction₂/NGAs；

(4) Uniformly mixing ferric nitrate, nickel nitrate, ammonium fluoride, urea and water, and adding the MoS obtained in the step (3)₂In the/NGAs, standing to obtain a second mixed solution;

(5) carrying out hydrothermal reaction on the second mixed solution obtained in the step (4) in a transfer reaction kettle, and drying to obtain Fe-Ni LDH-MoS₂/NGAs hydrogen evolution materials.

2. A Fe-Ni LDH-MoS as claimed in claim 1₂The preparation method of the/NGAs hydrogen evolution material is characterized in that in the step (1), the volume ratio of the graphene oxide suspension to the ethylenediamine is 5: 1.

3. a Fe-Ni LDH-MoS as claimed in claim 1₂The preparation method of the/NGAs hydrogen evolution material is characterized in that in the step (1), the reaction temperature is 150-.

4. A Fe-Ni LDH-MoS as claimed in claim 1₂The preparation method of the/NGAs hydrogen evolution material is characterized in that in the step (2), the molar ratio of sodium molybdate to thioacetamide is 3: 4; the dosage ratio of the sodium molybdate to the water is 3 mmol: (150- & lt 250- & gt) mL.

5. A Fe-Ni LDH-MoS as claimed in claim 1₂The preparation method of the/NGAs hydrogen evolution material is characterized in that in the step (3), the reaction temperature is 150-.

6. A Fe-Ni LDH-MoS as claimed in claim 1₂The preparation method of the/NGAs hydrogen evolution material is characterized in that in the step (4), the dosage ratio of the ferric nitrate, the nickel nitrate, the ammonium fluoride, the urea and the water is 2 mmol: 3 mmol: 3 mmol: 1 mmol: 30 ml.

7. The method for preparing Fe-Ni LDH-MoS2/NGAs hydrogen evolution material as claimed in claim 1, wherein in the step (5), the reaction temperature is 110-150 ℃ and the reaction time is 10-15h in the hydrothermal reaction process.

8. Fe-Ni LDH-MoS prepared by the method of any one of claims 1 to 7₂/NGAs hydrogen evolution materials.

9. Fe-Ni LDH-MoS as claimed in claim 8₂Use of/NGAs hydrogen evolution materials, characterized in that the Fe-Ni LDH-MoS₂the/NGAs hydrogen evolution material is used for electrocatalytic hydrogen and oxygen evolution reaction.

10. An Fe-Ni LDH-MoS as claimed in claim 9₂The application of/NGAs hydrogen evolution material is characterized in that Fe-Ni LDH-MoS is added₂the/NGAs hydrogen evolution material is uniformly mixed with Nafion solution, then is dripped on a glassy carbon electrode, and is dried to obtain the hydrogen evolution glassy carbon electrode which is used as a working electrode in the electrocatalytic hydrogen evolution reaction.