CN109092341A - The nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated and preparation - Google Patents

Abstract

The present invention provides a kind of nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated and its preparations.The nitrogen-doped carbon nanocomposite of the hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated, which is characterized in that including hollow nitrogen-doped carbon material, the hollow nitrogen-doped carbon material is coated with Copper-cladding Aluminum Bar cobalt oxide nickel.Composite material prepared by the present invention has the characteristics that structure and morphology is uniform, the hollow nitrogen-doped porous carbon material as derived from ZIF-67 and polyaniline supports the hollow polyhedron structure of the composite material, the doping of copper changes the distribution of charges of cobalt oxide nickel eigenstate, enhances its catalytic performance；The cobalt oxide nickel of Copper-cladding Aluminum Bar is uniformly grown in the outside of hollow nitrogen-doped carbon material, avoids metal oxide and is easy to the problem of reuniting, and has many advantages, such as that large specific surface area, good conductivity, physicochemical properties are stable, chemical property is superior.

Description

The nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated and preparation

Technical field

The invention belongs to Heteroatom doping bimetallic oxide-carbon material technical fields, and in particular to a kind of hollow copper is mixed The nitrogen-doped carbon nanocomposite and preparation method thereof of miscellaneous cobalt oxide nickel coated.

Background technique

Electro-catalysis hydrolysis causes great research interest as a kind of sustainable hydrogen production process.In two kinds of electrolysis waters In half-cell reaction, anode oxygen evolution reaction (OER) is related to higher four electronic transfer process of energy requirement, significantly reduces The efficiency of water decomposition.Therefore, the exploitation of OER effective catalyst is still one of most important challenge of water decomposition hydrogen manufacturing.Noble metal Oxide such as IrO_xAnd RuO_xSo far as the highest catalyst OER of activity of elctro-catalyst, but due to its scarcity, The reasons such as high cost and low durability and be unfavorable for its large-scale commercial applications application.

In order to evade the high cost and scarcity of noble metal-based catalysts (base metal), for example, transition metal oxide and The catalyst such as the carbon material of Heteroatom doping have caused extensive concern, and in alkaline environment in show it is excellent OER catalytic activity.However, the feature of unstability and the active site deficiency of non-precious metal catalyst seriously hinders it into one The development and application of step.The improved method of existing transition metal oxide has many aspects, and the hetero atom including catalyst is mixed Miscellaneous, defect project, structure design etc..Heteroatom doping strategy in catalyst of transition metal oxide can effectively change Become the distribution of charges of material itself and significant raising is made to its catalytic performance.And composite material structure design be can be straight The big factor for influencing material catalytic activity is connect, such as in catalysis reaction, hollow nanostructured catalyst can will be a large amount of Outer surface be exposed to reactant, there is sufficient reactive surfaces site due to high specific surface area, and by will be anti- It answers in object limitation in a limited space and allows to increase collision frequency, this can cooperate with enhancing catalytic activity, improve catalyst Efficiency.

Based on this, the present invention is prepared for the cobalt oxide nickel of Copper-cladding Aluminum Bar using the strategy of Heteroatom doping, and combines hollow receive The design of rice structure, is prepared for the nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated.Its Heteroatom doping Design substantially increase OER catalytic activity；Meanwhile hollow structure design increases the active site of composite material and than table Area substantially increases performance of composite material when as catalyst, shows outstanding OER catalytic activity.

Summary of the invention

Technical problem to be solved by the invention is to provide a kind of material with higher OER catalytic activity and its preparation sides Method.

In order to solve the above-mentioned technical problems, the present invention provides following technical solutions:

A kind of nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated, which is characterized in that including hollow Nitrogen-doped carbon material, the hollow nitrogen-doped carbon material are coated with Copper-cladding Aluminum Bar cobalt oxide nickel.

Preferably, the hollow nitrogen-doped carbon material is hollow polyhedron structure.

The present invention also provides the systems of the nitrogen-doped carbon nanocomposite of above-mentioned hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated Preparation Method characterized by comprising a strata aniline is coated on the surface ZIF-67, obtains ZIF-67@polyaniline composite material, Obtained ZIF-67@polyaniline composite material is obtained into hollow polyaniline by acid etch；Hollow polyaniline is subjected to high temperature again Carbonization treatment obtains hollow nitrogen-doped carbon material；Again via chemical codeposition, the nickel cobalt layered bi-metal of cladding Copper-cladding Aluminum Bar is obtained The hollow nitrogen-doped carbon material of hydroxide (copper-nickel cobalt LDH)；Finally hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated is obtained by annealing Nitrogen-doped carbon nanocomposite.

Preferably, the preparation method of the ZIF-67@polyaniline composite material includes: that ZIF-67 powder is dispersed in water In, ultrasonic disperse is uniform, obtains dispersion liquid, then aniline monomer is added in above-mentioned dispersion liquid, and it is evenly dispersed, then, incited somebody to action Ammonium sulfate is added in above-mentioned dispersion liquid, is stirred to react, and obtained sediment is centrifuged, and is washed, dry, obtains ZIF- 67@polyaniline composite materials.

It is highly preferred that the concentration of ZIF-67 is 0.5-1.5mg/mL, more preferably 1 mg/mL in the dispersion liquid.

It is highly preferred that the mass concentration of the ammonium persulfate solution is 0.02-0.03g/mL.

It is highly preferred that the time being stirred to react is 8-14h.

It is highly preferred that the mass ratio of the ZIF-67 powder and aniline monomer, ammonium persulfate is 100: 0.01- 0.05∶750-1100。

Preferably, the acid etch includes: to immerse the powder of ZIF-67@polyaniline composite material in hydrochloric acid solution, Stirring performs etching reaction, etches away internal ZIF-67, obtains hollow polyaniline.

It is highly preferred that the concentration of the hydrochloric acid solution is 0.5-1.5mol/L, etch period 5-7h.It is highly preferred that The concentration of the hydrochloric acid solution is 1mol/L, etch period 6h.

Preferably, high temperature cabonization processing includes that hollow polyaniline is placed in tube furnace, in inert gas or nitrogen Atmosphere encloses lower high-temperature process, obtains hollow nitrogen-doped carbon material.

It is highly preferred that the treatment temperature is 700-900 DEG C, time 2-5h, heating rate is 3-10 DEG C/min.

It is highly preferred that inert gas used is argon gas, the temperature of heat treatment is 800 DEG C, heat treatment time 3h, is risen Warm rate is 5 DEG C/min.

Preferably, the specific steps of the chemical codeposition include: by Nickelous nitrate hexahydrate, cabaltous nitrate hexahydrate and six Methenamine is dissolved in the ethanol/water mixed solvent containing micro copper nitrate, and ultrasonic treatment makes it be uniformly dispersed, will be hollow Nitrogen-doped carbon material is added in the ethanol/water mixed solution, ultrasonic disperse, oil bath heating, and it is anti-that stirring carries out chemical codeposition It answers, the mixed-powder that reaction obtains is collected by centrifugation, wash, it is dry, obtain the nickel cobalt layered bi-metal of cladding Copper-cladding Aluminum Bar The hollow nitrogen-doped carbon material of hydroxide (copper-nickel cobalt LDH).

It is highly preferred that the molar ratio of the Nickelous nitrate hexahydrate, cabaltous nitrate hexahydrate and hexa is 1-4: 1-6:7-14.More preferably 1: 2: 10.

It is highly preferred that in the ethanol/water mixed solvent containing micro copper nitrate copper nitrate concentration be 0.5 × 10^-3-3×10^-3Mol/L, the ratio of second alcohol and water are 1-2: 1-4.More preferably 1: 1.

It is highly preferred that the sonication treatment time is 5-20min, more preferably 10min, the ultrasonic disperse time is 1- 3h, more preferably 2h.

It is highly preferred that the oil bath heating temperature is 60-100 DEG C, time 6-12h, and more preferably 80 DEG C, when heating Between be 8h

It is highly preferred that the washing is carried out with the mixed solution of second alcohol and water, drying temperature is 60 DEG C, time 10- 16h, more preferably 12h.

Preferably, the annealing includes the nickel cobalt layered double hydroxide (copper-nickel cobalt LDH) that will coat Copper-cladding Aluminum Bar Hollow nitrogen-doped carbon material powder be placed in tube furnace and made annealing treatment in inert atmosphere or nitrogen, obtain hollow Copper-cladding Aluminum Bar The nitrogen-doped carbon nanocomposite of cobalt oxide nickel coated.

It is highly preferred that the annealing temperature is 250-500 DEG C, time 1-3h.More preferable annealing temperature is 350 DEG C, The processing time is 2h, and inert gas used is argon gas.

The present invention also provides the nitrogen-doped carbon nanocomposites of above-mentioned hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated to make For the application of catalyst in OER.

ZIF-67 is prepared by solution stirring method in the present invention, then coats a strata aniline on the surface ZIF-67 again； Obtained ZIF-67@polyaniline composite material is obtained into hollow polyaniline by acid etch；Hollow polyaniline is subjected to high temperature again The treatment process of carbonization obtains hollow nitrogen-doped carbon material；The stratiform nickel cobalt bimetallic of Copper-cladding Aluminum Bar is obtained via chemical codeposition again Hydroxide (copper-nickel cobalt LDH)；Its last preparation process by annealing obtains a kind of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated Nitrogen-doped carbon nanocomposite.It is characterised by comprising: it is uniform to be prepared for structure and morphology by by the method for polymerisation in solution ZIF-67, and coated a strata aniline on its surface；ZIF-67@polyaniline composite material is removed into ZIF- by acid etch 67, obtain hollow polyaniline；High temperature cabonization is carried out again, obtains hollow nitrogen-doped carbon material；Finally, using chemical coprecipitation Product and the preparation process of annealing obtain a kind of hollow nitrogen-doped carbon nanocomposite of cobalt oxide nickel of Copper-cladding Aluminum Bar.

The present invention is prepared for the cobalt oxide nickel of Copper-cladding Aluminum Bar using the strategy of Heteroatom doping, and combines hollow nanostructures Design, is prepared for the nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated.The design of its Heteroatom doping is big OER catalytic activity is improved greatly；Meanwhile hollow structure design increases the active site and specific surface area of composite material, greatly Performance of composite material when as catalyst is improved greatly, shows outstanding OER catalytic activity.

Composite material prepared by the present invention has the characteristics that structure and morphology is uniform, is spread out by ZIF-67 polyaniline composite material Raw hollow nitrogen-doped porous carbon material supports the hollow polyhedron structure of the composite material, and the doping of copper changes oxygen The distribution of charges for changing cobalt nickel eigenstate, enhances its catalytic performance；The cobalt oxide nickel of Copper-cladding Aluminum Bar is uniformly grown in hollow nitrogen and mixes The outside of miscellaneous carbon material avoids metal oxide and is easy to the problem of reuniting, and has large specific surface area, good conductivity, physico Learn the advantages that property is stable, chemical property is superior.

Conventional cobalt oxide nickel material has been carried out Copper-cladding Aluminum Bar by the present invention, is manufactured that using ZIF-67 and polyaniline hollow Nanostructure, and the two is combined to have obtained the nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated.

Compared with prior art, the beneficial effects of the present invention are:

1, experimental design logicality is strong, and preparation process is rigorously mature, it is adapted to study and apply on a large scale.

2, the present invention carries out the doping of copper in conventional cobalt oxide nickel, changes the charge of cobalt oxide nickel eigenstate It is distributed and is improved catalytic performance, is a kind of method of modifying being simple and efficient.

3, hollow nitrogen-doped carbon material has been obtained using ZIF-67 and polyaniline as reacting precursor, both successfully obtained Empty nanostructure, and successfully introduce nitrogen-doped carbon.The specific surface area of product is high, and structure is uniform, and there is excellent electricity to urge Change performance.

Detailed description of the invention

Fig. 1 is the preparation flow of the nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated in the present invention Figure.

Fig. 2 is the XPS map of the nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated in the present invention.

Fig. 3 is the XRD spectrogram of the nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated in the present invention.

Fig. 4 be using the nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated obtained in the present invention as The catalyst of OER, obtained OER performance atlas.Scheming a curve is hollow Copper-cladding Aluminum Bar cobalt oxide nickel packet obtained in embodiment 1 The OER polarization curve of the nitrogen-doped carbon nanocomposite covered, figure b is corresponding Tafel curve.

Specific embodiment

Present invention will be further explained below with reference to specific examples.It should be understood that these embodiments are merely to illustrate the present invention Rather than it limits the scope of the invention.In addition, it should also be understood that, after reading the content taught by the present invention, those skilled in the art Member can make various changes or modifications the present invention, and such equivalent forms equally fall within the application the appended claims and limited Range.

Embodiment 1

A kind of nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated, including hollow N doping carbon materials Material, the hollow nitrogen-doped carbon material are coated with Copper-cladding Aluminum Bar cobalt oxide nickel.The hollow nitrogen-doped carbon material is hollow Polyhedral structure.

The nitrogen-doped carbon nanocomposite of the hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated the preparation method comprises the following steps:

Step 1: coating a strata aniline on the surface ZIF-67, ZIF-67@polyaniline composite material is obtained, by what is obtained ZIF-67@polyaniline composite material obtains hollow polyaniline by acid etch:

ZIF-67 powder is dispersed in the water of 100mL, the uniform 20min of ultrasonic disperse obtains dispersion liquid, ZIF-67's Concentration is 1mg/mL.20 μ L aniline (Sigma-Aldrich) monomers are added in above-mentioned dispersion liquid again, it is made to be uniformly dispersed. Then, the ammonium persulfate (Sinopharm Chemical Reagent Co., Ltd.) of 0.95g, ultrasonic treatment are dissolved in the deionized water of 30mL It is added to after 10min in above-mentioned dispersion liquid, and is stirred to react 12h.Obtained sediment is centrifuged, then is washed with deionized 3 times, ZIF-67@polyaniline composite material is obtained within dry 12 hours in 60 DEG C.By obtained ZIF-67@polyaniline composite material Powder immerse in the hydrochloric acid solution of 200 mL1mol/L, stirring performs etching reaction 6h, etches away internal ZIF-67, obtains Hollow polyaniline.

Step 2: handling hollow polyaniline progress high temperature cabonization to obtain hollow nitrogen-doped carbon material again: by hollow polyaniline It is placed in tube furnace, 800 DEG C of processing 3h under argon atmosphere, heating rate is 5 DEG C/min, obtains hollow nitrogen-doped carbon material.

Step 3: via chemical codeposition, obtaining the nickel cobalt layered double hydroxide (copper-nickel cobalt of cladding Copper-cladding Aluminum Bar LDH hollow nitrogen-doped carbon material):

By 110mg Nickelous nitrate hexahydrate (Sinopharm Chemical Reagent Co., Ltd.), 221mg cabaltous nitrate hexahydrate (traditional Chinese medicines Chemical reagent Co., Ltd of group), 560mg hexa (Sigma-Aldrich) is dissolved in 40mL and contains 6 × 10^-5mol Copper nitrate ethanol/water mixed solvent in (volume ratio of second alcohol and water be 1: 1), and be ultrasonically treated 10min, make its dispersion Uniformly；The hollow nitrogen-doped carbon of 25mg is added in the ethanol/water mixed solution again, ultrasonic disperse 2h；With oil bath heating to 80 DEG C, 8h is stirred, is allowed to carry out the reaction process of chemical codeposition；And then the mixed-powder that reaction obtains is subjected to centrifugation receipts The mixed solution of collection, the second alcohol and water for being 1: 1 with volume ratio washs, and the dry 12h at 60 DEG C, obtains the nickel of cladding Copper-cladding Aluminum Bar The hollow nitrogen-doped carbon material of cobalt layered double hydroxide (copper-nickel cobalt LDH).

Step 4: the preparation of the nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated:

Obtained mix powder is placed in tube furnace, is made annealing treatment in argon atmosphere at 350 DEG C, the time is 2h obtains the nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated.

The present invention is characterized, tested using x-ray photoelectron spectroscopy (XPS), X-ray diffraction (XRD), electrochemical workstation The composed structure and performance of the nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated obtained, result is such as Under:

(1) XPS test result shows: existing in the nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated C, O, Ni, Co and Cu element.As shown in Fig. 2, four more apparent peaks being located in 800-900eV correspond respectively to the 2p of Co The 2p track of track and Ni, and be respectively the 2p of Cu element at the peak of 900-950eV or so two labels occurred_3/2Track and 2p_1/2Track, this also directly illustrates the successful doping of Cu element.The peak of 500eV or so correspond to O 1s track, 400eV and The absorption peak that 290eV or so occurs corresponds respectively to the 1s track of N and the 1s track of C, this illustrates nitrogen-doped carbon material and copper The success of the cobalt oxide nickel of doping is compound.

(2) XRD test result shows: as shown in figure 3, the hollow nitrogen-doped carbon nanocomposite of the cobalt oxide nickel of Copper-cladding Aluminum Bar XRD curve occur apparent 5 diffraction patterns at 31.3 °, 37.2 °, 43.9 °, 58.3 ° and 63.5 °, respectively correspond oxygen Change (220), (311), (400), (511) and (440) diffraction crystal face of cobalt nickel.XRD spectrum the result shows that experiment obtained in The nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated is combined by cobalt oxide nickel and nitrogen-doped carbon, this Also directly illustrate by preparation method provided by the present invention to be practicable referring to attached drawing 1.

(3) electrochemical workstation test result shows: in electro-chemical test, using three electrode test systems, with made The glass-carbon electrode of standby hybrid material modification is working electrode, and Ag/AgCl is reference electrode, and graphite rod is to electrode, institute's electricity consumption Solve the KOH solution that liquid is 1M.Before testing, electrolyte is led to 30 min of oxygen in advance makes amount of oxygen in electrolyte reach saturation. Using the electro catalytic activity of hybrid material prepared in the linear sweep voltammetry research present invention.OER is tested, polarization is bent Line is recorded on O₂In the 1M KOH electrolyte of saturation, voltage range is 0 to 0.9V (relative to Ag/AgCl) to compare, and is made All current potentials are converted into RHE value: E (RHE)=E (Ag/AgCl)+0.197+0.0591pH with following equation.Wherein, E It (RHE) is the potential relative to standard hydrogen electrode, unit is volt (V)；E (Ag/AgCl) is relative to silver/silver chlorate (Ag/ AgCl) the potential of electrode, unit are volt (V)；PH is the hydrogen ionexponent for testing environment solution.

The pretreatment of glass-carbon electrode: glass-carbon electrode is successively polished with 1.0,0.3,0.05 microns of alumina powder, Grind off the oxide layer and impurity on surface.It is cleaned after polishing with deionized water and EtOH Sonicate every time, last time uses nitrogen after polishing Air-blowing is done spare.

The preparation of modified electrode: made in the surface present invention by pretreated glass-carbon electrode using direct drop-coating Standby hybrid material is modified.Specially 350 μ L ethyl alcohol and 50 μ L 5wt% are dispersed by hybrid material prepared by 5mg Nafion solution forms uniform ink.Then after being ultrasonically treated 1h, take 30 μ L solution drop on platinum carbon electrode, at 70 DEG C Dry 0.5h is spare in baking oven.

The OER polarization curve (Fig. 4) of the nitrogen-doped carbon nanocomposite catalyst of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated Clearly demonstrate its excellent OER activity.For the nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated, In 10mAcm^-2Current density under, overpotential 400mV.The bright hollow copper of Ta Feier chart of corresponding catalyst The nitrogen-doped carbon nanocomposite catalyst for adulterating cobalt oxide nickel coated has 59mV dec^-1Tafel slope, during this shows There is the nitrogen-doped carbon nanocomposite of empty Copper-cladding Aluminum Bar cobalt oxide nickel coated preferable catalysis to live when as OER catalyst Property.

Embodiment 2

Similar to the nitrogen-doped carbon nanocomposite of the hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated of embodiment 1, difference is: Annealing temperature described in step 5 in embodiment 1 is changed to 450 DEG C, obtained Product Labeling is hollow Copper-cladding Aluminum Bar cobalt oxide nickel The nitrogen-doped carbon nanocomposite -1 of cladding.

Embodiment 3

Similar to the nitrogen-doped carbon nanocomposite of the hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated of embodiment 1, difference is: The heat treatment temperature of argon atmosphere described in step 3 in embodiment 1 is changed to 700 DEG C, obtained Product Labeling is hollow copper Adulterate the nitrogen-doped carbon nanocomposite -2 of cobalt oxide nickel coated.

Claims (9)

1. a kind of nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated, which is characterized in that including hollow nitrogen Carbon material is adulterated, the hollow nitrogen-doped carbon material is coated with Copper-cladding Aluminum Bar cobalt oxide nickel.

2. the nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated as described in claim 1, feature exist In the hollow nitrogen-doped carbon material is hollow polyhedron structure.

3. the nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated of any of claims 1 or 2, feature exist In, comprising: a strata aniline is coated on the surface ZIF-67, obtains ZIF-67@polyaniline composite material, the ZIF-67@that will be obtained Polyaniline composite material obtains hollow polyaniline by acid etch；Again hollow polyaniline progress high temperature cabonization is handled to obtain hollow Nitrogen-doped carbon material；Again via chemical codeposition, the hollow nitrogen of the nickel cobalt layered double hydroxide of cladding Copper-cladding Aluminum Bar is obtained Adulterate carbon material；Finally the nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated is obtained by annealing.

4. the nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated as claimed in claim 3, feature exist In the preparation method of the ZIF-67@polyaniline composite material includes: to be dispersed in water ZIF-67 powder, ultrasonic disperse Uniformly, obtain dispersion liquid, then aniline monomer be added in above-mentioned dispersion liquid, it is evenly dispersed, then, by ammonium persulfate solution plus Enter into above-mentioned dispersion liquid, be stirred to react, obtained sediment is centrifuged, washs, it is dry, it is multiple to obtain ZIF-67@polyaniline Condensation material.

5. the nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated as claimed in claim 3, feature exist In the acid etch includes: to immerse the powder of ZIF167@polyaniline composite material in hydrochloric acid solution, and stirring performs etching Reaction etches away internal ZIF-67, obtains hollow polyaniline.

6. the nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated as claimed in claim 3, feature exist In the high temperature cabonization processing includes that hollow polyaniline is placed in tube furnace, the high temperature under inert gas or nitrogen atmosphere Processing, obtains hollow nitrogen-doped carbon material.

7. the nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated as claimed in claim 3, feature exist In the specific steps of the chemical codeposition include: that Nickelous nitrate hexahydrate, cabaltous nitrate hexahydrate and hexa is molten Xie Yu contains in the ethanol/water mixed solvent of micro copper nitrate, and ultrasonic treatment makes it be uniformly dispersed, by hollow nitrogen-doped carbon material It is added in the ethanol/water mixed solution, ultrasonic disperse, oil bath heating, stirring carries out chemical codeposition reaction, and reaction is obtained Mixed-powder be collected by centrifugation, wash, it is dry, obtain the nickel cobalt layered double hydroxide (copper-nickel of cladding Copper-cladding Aluminum Bar Cobalt LDH) hollow nitrogen-doped carbon material.

8. the nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated as claimed in claim 3, feature exist In the annealing includes the hollow N doping that will coat the nickel cobalt layered double hydroxide (copper-nickel cobalt LDH) of Copper-cladding Aluminum Bar Carbon material powder is placed in tube furnace and is made annealing treatment in inert atmosphere or nitrogen, obtains hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated Nitrogen-doped carbon nanocomposite.

9. the nitrogen-doped carbon nanocomposite of hollow Copper-cladding Aluminum Bar cobalt oxide nickel coated of any of claims 1 or 2 is as OER The application of middle catalyst.