CN108543546A - The preparation method of graphite phase carbon nitride photochemical catalyst with visible light catalysis activity - Google Patents

Abstract

A kind of preparation method of the graphite phase carbon nitride photochemical catalyst with visible light catalysis activity, carries out according to the following steps：(1) ethylenediamine tetra-acetic acid powder is mixed with aggressiveness before carbonitride and is ground uniformly, mixed-powder is made；(2) mixed-powder is warming up to 450~600 DEG C, then heat preservation carries out copolyreaction, then cools to room temperature with the furnace, and graphite phase carbon nitride photochemical catalyst is made.The method of the present invention is of low cost, meets actual production demand, simple for process, has wide economy and actual application prospect；The graphite phase carbon nitride of preparation can easily carry out separating treatment, high recycling rate with efficient degradation methyl orange in light-catalyzed reaction system.

Description

The preparation method of graphite phase carbon nitride photochemical catalyst with visible light catalysis activity

Technical field

The invention belongs to non-metal optical catalyst technical field, more particularly to a kind of graphite with visible light catalysis activity The preparation method of phase carbon nitride photochemical catalyst.

Background technology

Graphite phase carbon nitride is a kind of novel non-metal optical catalysis material, with traditional TiO₂, ZnO, the early stage such as platinum palladium Catalysis material is compared, and the carbon of carbon nitride material and the rich reserves of nitrogen, carbon nitride material preparation process letter are formed Single, environmental-friendly, in addition graphite phase carbon nitride material has two dimensional surface lamellar structure, therefore has very high specific surface Product；These advantages make graphite phase carbon nitride material by the extensive concern of researcher, and light degradation environmental contaminants with And there is potential application in the fields such as photocatalytic cleavage water.

But there is also problems for graphite phase carbon nitride；First, it is limited by own electronic structure, graphite-phase nitrogen The band gap width for changing carbon is generally higher than 2.7ev, thus the material can only absorbing wavelength be less than the sunlight of 450nm, for the sun Light utilization ratio is relatively low so that catalytic inner carrier concentration is low；Secondly, the hole generated after photon and photoproduction are absorbed Electronics is easy to compound, can not be transmitted to catalyst surface and participate in light-catalyzed reaction.These disadvantages make graphite phase carbon nitride in reality Catalytic efficiency is very low in the use of border, can not be with classical semiconductor catalyst such as TiO₂And noble metal catalyst such as platinum palladium chtalyst Agent compares.

Since the catalytic property of graphite phase carbon nitride and its own pi-conjugated electronic structure have close contact, The electronic structure of graphite phase carbon nitride can be changed by way of doping and then regulate and control its energy gap, improve material too Sunlight utilization, and then photoproduction carrier concentration is improved, improve the catalytic efficiency of catalyst；Meanwhile Reasonable Regulation And Control dopant Type and content can regulate and control highest occupied molecular orbital (HOMO tracks) and lowest unoccupied molecular orbital (LUMO tracks) distribution of catalyst, promote Into the separation of photogenerated charge and hole, the photocatalytic activity of catalyst is further increased；Seminar of king Xinchen of University of Fuzhou utilizes Graphite phase carbon nitride (the Chinese invention patent with visible light catalysis activity is made with urea copolymerization in 2- aminothiophene -3- formonitrile HCNs CN103272639B), the copolymerization small molecule but used in this method is expensive；Tongji University's Feng's thunderstorm et al. utilizes sulphur powder With cyanogen ammonia hybrid reaction, it is prepared for the graphite phase carbon nitride (Chinese invention patent with the sulfur doping of photocatalytic activity CN104056648 B), but the monomer cyanogen ammonia used in it has toxicity, and there are security risks.

Invention content

For the above problem existing for existing graphite phase carbon nitride photochemical catalyst technology of preparing, the present invention, which provides one kind, to be had The preparation method of the graphite phase carbon nitride photochemical catalyst of visible light catalysis activity makes graphite-phase nitrogen by adulterating ethylenediamine tetra-acetic acid Changing carbon, there is adjustable band gap width, quick photo-generated carrier separating capacity organic matter is realized under visible light conditions Fast degradation.

The method of the present invention carries out according to the following steps：

1, ethylenediamine tetra-acetic acid powder is mixed with aggressiveness before carbonitride and is ground uniformly, mixed-powder is made；Described Aggressiveness is urea or melamine before carbonitride；

2, mixed-powder is warming up to 450~600 DEG C, then heat preservation carries out copolyreaction, then cools to room temperature with the furnace, makes At graphite phase carbon nitride photochemical catalyst.

The reaction equation of above-mentioned step 2 copolyreaction is：

Or it is：

In the above method, the mass ratio of aggressiveness and ethylenediamine tetra-acetic acid is 10 before carbonitride:(0.01~0.2).

In the above method, heating rate is 0.5~10 DEG C/min.

In the above method, soaking time is 1~4h.

Beneficial effects of the present invention are：

1, urea and melamine are simply less toxic compared to reactants such as cyanogen ammonia, of low cost, meet actual production demand, It is simple for process, there is wide economy and actual application prospect；

2, the graphite phase carbon nitride prepared has adjustable band gap width, improves the absorption efficiency of visible light, simultaneously The photo-generated carrier separation of catalytic inner, transport efficiency are improved；

3, the graphite phase carbon nitride prepared can be with efficient degradation methyl orange, relative to no copolymerization ethylenediamine tetra-acetic acid molecule Graphite phase carbon nitride, degradation rate can be enhanced about more than once；Meanwhile prepared catalyst is in light-catalyzed reaction system Separating treatment can be easily carried out, high recycling rate has very high practical value and is widely applied foreground.

Description of the drawings

Fig. 1 is graphite phase carbon nitride photochemical catalyst and traditional undoped ethylenediamine tetra-acetic acid in the embodiment of the present invention The TEM photo figures of graphite phase carbon nitride；In figure, A and B are the graphite phase carbon nitride undoped with ethylenediamine tetra-acetic acid, and C and D are real Example 2 is applied, E and F are embodiment 3；

Fig. 2 is graphite phase carbon nitride photochemical catalyst and traditional undoped ethylenediamine tetra-acetic acid in the embodiment of the present invention The XRD diagram of graphite phase carbon nitride；In figure each curve be followed successively by from top to bottom undoped with ethylenediamine tetra-acetic acid graphite phase carbon nitride, Embodiment 1, embodiment 2, embodiment 3 and embodiment 4；

Fig. 3 is graphite phase carbon nitride photochemical catalyst and traditional undoped ethylenediamine tetra-acetic acid in the embodiment of the present invention The Fourier transform infrared FT-IR figures of graphite phase carbon nitride；Each curve is followed successively by from top to bottom undoped with ethylenediamine tetrem in figure Graphite phase carbon nitride, embodiment 2 and the embodiment 4 of acid；

Fig. 4 is graphite phase carbon nitride photochemical catalyst and traditional undoped ethylenediamine tetra-acetic acid in the embodiment of the present invention The wavelength of graphite phase carbon nitride-absorbance curve figure；Each curve is followed successively by embodiment 4, embodiment 3, implements from top to bottom in figure Example 2, embodiment 1 and the graphite phase carbon nitride undoped with ethylenediamine tetra-acetic acid；

Fig. 5 is graphite phase carbon nitride photochemical catalyst and traditional undoped ethylenediamine tetra-acetic acid in the embodiment of the present invention The appearance photo figure of graphite phase carbon nitride；In figure, upper row is from left to right followed successively by the graphite-phase nitrogen undoped with ethylenediamine tetra-acetic acid Change carbon, embodiment 1 and embodiment 2, lower row is from left to right embodiment 3 and embodiment 4；

Fig. 6 is graphite phase carbon nitride photochemical catalyst and traditional undoped ethylenediamine tetra-acetic acid in the embodiment of the present invention (the ah ν) of graphite phase carbon nitride²- h ν curve graphs；In figure, ━ is the graphite phase carbon nitride undoped with ethylenediamine tetra-acetic acid, and ★ is Embodiment 1, ◆ it is embodiment 2, ▲ it is embodiment 3, ● it is embodiment 4；

Fig. 7 is graphite phase carbon nitride photochemical catalyst and traditional undoped ethylenediamine tetra-acetic acid in the embodiment of the present invention The wavelength of graphite phase carbon nitride-fluorescence intensity curves figure；In figure, ━ is the graphite phase carbon nitride undoped with ethylenediamine tetra-acetic acid, ★ is embodiment 1, ◆ it is embodiment 2, ▲ it is embodiment 3, ● it is embodiment 4；

Fig. 8 is graphite phase carbon nitride photochemical catalyst and traditional undoped ethylenediamine tetra-acetic acid in the embodiment of the present invention Degradation rate curve graph of the graphite phase carbon nitride to methyl orange；Each curve is followed successively by from top to bottom in figure does not add graphite-phase nitridation Carbon adds the graphite phase carbon nitride undoped with ethylenediamine tetra-acetic acid, adds the product of embodiment 1, adds the product of embodiment 2, The product of embodiment 4 is added, the product of embodiment 3 is added；

Fig. 9 is that the graphite phase carbon nitride photochemical catalyst in the embodiment of the present invention 2 reuses curve to the degradation of methyl orange Figure；In figure, be followed successively by from left to right degradation is primary, degradation is secondary, degradation three times, degradation four times and degradation five times.

Specific implementation mode

It carries out that mixed-powder being placed in the crucible with lid when copolyreaction in the embodiment of the present invention, then in horse Copolyreaction is not carried out in stove.

The ethylenediamine tetra-acetic acid powder purity 98% used in the embodiment of the present invention, urea crystal purity 99%, melamine Amine purity is 99%, is Sigma Aldrich products.

The transmission electron microscope model JEOL1230 used in the embodiment of the present invention.

The model Rigaku Ultima III of the X-ray diffractometer used in the embodiment of the present invention.

The Fourier transform infrared FT-IR unit types used in the embodiment of the present invention is Vertex 80Bruket.

In the embodiment of the present invention (ah ν)²- h ν curve unit types are Cary 5000, use pattern for diffusing reflection pattern.

Test wavelength-fluorescence intensity unit type is Fluoro Max 3 in the embodiment of the present invention.

The method of product purity test is in the embodiment of the present invention：By the doped graphite phase carbon nitride photocatalysis of 0.2g/ml Agent is put into 100ml, and in the methyl orange solution of 8mg/L, sample is made；Sample is placed in processing 1h at dark, makes up to balance； With equipped with 400nm optical filters, intensity 100mW/cm²Light source AM1.5 simulated solar light sources, pass through the quartz of a diameter of 1cm Window irradiates sample, and absorbance of the methyl orange when wavelength is 400nm is surveyed by Cary5000 UV, visible light infrared spectrometers, from And judge the surplus of methyl orange.

After carrying out Degrading experiment using graphite phase carbon nitride photochemical catalyst in the embodiment of the present invention, pass through consolidating for centrifugation After phase drying removes moisture removal, reused as graphite phase carbon nitride photochemical catalyst.

The present invention carries out contrast test using graphite phase carbon nitride of the tradition undoped with ethylenediamine tetra-acetic acid, with the application reality The graphite phase carbon nitride photochemical catalyst applied in example 1~4 is compared；TEM photos are as shown in Figure 1, as seen from the figure, undoped with second two The graphite phase carbon nitride of amine tetraacethyl is lamellar structure, adulterates the graphite phase carbon nitride of ethylenediamine tetra-acetic acid, symbolizes doping production Lattice defect is given birth to, the generation of irregular holes can increase surface area, and defect can adjust visible absorption range；XRD is such as Shown in Fig. 2, as seen from the figure, product occurs two at 13.1 ° and 27.4 ° and significantly belongs to graphite phase carbon nitride (100) (002) diffraction maximum of crystal face；Fourier transform infrared FT-IR figures are as shown in figure 3, as seen from the figure, product is in 800cm^-1Belong to The breathing vibration of piperazine ring, 1200~1600cm^-1The peak at place belongs to the stretching vibration of heterocycle, in 3200cm^-1The broad peak at place is main It is the more NH and NH not being bonded existing for nitridation carbon surface₂Caused stretching vibration；Wavelength-absorbance curve such as Fig. 4 institutes Show, as seen from the figure, undoped graphite phase carbon nitride is less than 450nm to the absorption of visible light, very low to the utilization rate of visible light, Doped graphite phase carbon nitride, in 550nm or so, largely increases graphite phase carbon nitride and urges to the absorption of visible light Absorption of the agent to visible light；Appearance photo as shown in figure 5, with ethylenediamine tetra-acetic acid doping increase, the color of product Gradually deepen, it is known that the absorption region of visible light is changed；(ahν)²- h ν curves are as shown in fig. 6, undoped with state The energy gap of graphite phase carbon nitride is 2.80ev, and with the increase of ethylenediamine tetra-acetic acid doping, current-carrying electrons migration occurs The band gap width that required energy reduces graphite phase carbon nitride narrows, and the absorption region and utilization rate to visible light increase；By Fig. 4,6 are it is found that doped graphite phase carbon nitride increases the absorption of visible light, and energy gap narrows；Wavelength-fluorescence is strong Line write music as shown in fig. 7, as seen from the figure, the fluorescence intensity for adulterating the graphite phase carbon nitride photochemical catalyst of ethylenediamine tetra-acetic acid is apparent It reduces, illustrates the separative efficiency for effectively increasing charge by adulterating carbon nitride photocatalyst；It is bent to the degradation rate of methyl orange Line as shown in figure 8, the methyl orange for not adding graphite phase carbon nitride is hardly degraded, be added traditional graphite phase carbon nitride for Methyl orange has certain degradation capability, reacts 5 hours, has 60% or so not degrade, relative to no doping ethylenediamine The graphite phase carbon nitride of tetrem acid molecule, degradation capability can be increased by being doped with the graphite phase carbon nitride of ethylenediamine tetra-acetic acid, instead 5 hours undegradable percentage are answered to be respectively less than the graphite phase carbon nitride undoped with state；Wherein it is doped with 0.10g ethylenediamine tetra-acetic acids Graphite phase carbon nitride can be enhanced about more than once for the degradation rate of methyl orange, 5 hours of reaction only have 10% or so and do not have There is degradation；Curve is reused to the degradation of methyl orange as shown in figure 9, with the increase for reusing number, centrifugation successively is received Doped carbonitride after collection still there is higher degradation capability, photocatalytic activity not to have great changes, explanation methyl orange The high recycling rate of product.

Embodiment 1

Ethylenediamine tetra-acetic acid powder is mixed with urea crystal and is ground uniformly, mixed-powder, wherein urea and second is made The mass ratio of ethylenediamine tetraacetic acid (EDTA) is 10:0.01；

Mixed-powder is warming up to 600 DEG C with the heating rate of 10 DEG C/min, then heat preservation 1h progress copolyreaction, then with Stove is cooled to room temperature, and graphite phase carbon nitride photochemical catalyst is made.

Embodiment 2

Ethylenediamine tetra-acetic acid powder is mixed with urea crystal and is ground uniformly, mixed-powder, wherein urea and second is made The mass ratio of ethylenediamine tetraacetic acid (EDTA) is 10:0.05；

Mixed-powder is warming up to 550 DEG C with the heating rate of 5 DEG C/min, then heat preservation 2h progress copolyreaction, then with Stove is cooled to room temperature, and graphite phase carbon nitride photochemical catalyst is made.

Embodiment 3

Ethylenediamine tetra-acetic acid powder is mixed with urea crystal and is ground uniformly, mixed-powder, wherein urea and second is made The mass ratio of ethylenediamine tetraacetic acid (EDTA) is 10:0.1；

Mixed-powder is warming up to 500 DEG C with the heating rate of 2 DEG C/min, then heat preservation 3h progress copolyreaction, then with Stove is cooled to room temperature, and graphite phase carbon nitride photochemical catalyst is made.

Embodiment 4

Ethylenediamine tetra-acetic acid powder is mixed with urea crystal and is ground uniformly, mixed-powder, wherein urea and second is made The mass ratio of ethylenediamine tetraacetic acid (EDTA) is 10:0.2；

Mixed-powder is warming up to 450 DEG C with the heating rate of 0.5 DEG C/min, 4h is then kept the temperature and carries out copolyreaction, then It cools to room temperature with the furnace, graphite phase carbon nitride photochemical catalyst is made.

Embodiment 5

Ethylenediamine tetra-acetic acid powder is mixed with melamine and is ground uniformly, mixed-powder, wherein melamine is made Mass ratio with ethylenediamine tetra-acetic acid is 10:0.01；

Mixed-powder is warming up to 450 DEG C with the heating rate of 0.5 DEG C/min, 4h is then kept the temperature and carries out copolyreaction, then It cools to room temperature with the furnace, graphite phase carbon nitride photochemical catalyst is made.

Embodiment 6

Ethylenediamine tetra-acetic acid powder is mixed with melamine and is ground uniformly, mixed-powder, wherein melamine is made Mass ratio with ethylenediamine tetra-acetic acid is 10:0.1；

Mixed-powder is warming up to 500 DEG C with the heating rate of 2 DEG C/min, then heat preservation 4h progress copolyreaction, then with Stove is cooled to room temperature, and graphite phase carbon nitride photochemical catalyst is made.

Embodiment 7

Ethylenediamine tetra-acetic acid powder is mixed with melamine and is ground uniformly, mixed-powder, wherein melamine is made Mass ratio with ethylenediamine tetra-acetic acid is 10:0.2；

Mixed-powder is warming up to 600 DEG C with the heating rate of 10 DEG C/min, then heat preservation 4h progress copolyreaction, then with Stove is cooled to room temperature, and graphite phase carbon nitride photochemical catalyst is made.

Claims (4)

1. a kind of preparation method of the graphite phase carbon nitride photochemical catalyst with visible light catalysis activity, it is characterised in that by following Step carries out：

(1) ethylenediamine tetra-acetic acid powder is mixed with aggressiveness before carbonitride and is ground uniformly, mixed-powder is made；The nitridation Aggressiveness is urea or melamine before carbon；

(2) mixed-powder is warming up to 450~600 DEG C, then heat preservation carries out copolyreaction, then cools to room temperature with the furnace, is made Graphite phase carbon nitride photochemical catalyst.

2. a kind of preparation side of graphite phase carbon nitride photochemical catalyst with visible light catalysis activity according to claim 1 Method, it is characterised in that the mass ratio of aggressiveness and ethylenediamine tetra-acetic acid is 10 before carbonitride in step (1):(0.01~0.2).

3. a kind of preparation side of graphite phase carbon nitride photochemical catalyst with visible light catalysis activity according to claim 1 Method, it is characterised in that the heating rate in step (2) when heating is 0.5~10 DEG C/min.

4. a kind of preparation side of graphite phase carbon nitride photochemical catalyst with visible light catalysis activity according to claim 1 Method, it is characterised in that soaking time is 1~4h in step (2).