CN110736770A - N-GQDs modified 3DOM In2O3Composite material and preparation method and application thereof - Google Patents
N-GQDs modified 3DOM In2O3Composite material and preparation method and application thereof Download PDFInfo
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Abstract
The invention belongs to the technical field of nano materials, and discloses N-GQDs modified 3DOM In2O3Composite material and its preparation method and application. The composite material is composed of 3DOM In2O3And N-GQDs uniformly loaded on the surface and in the pore channels. Dispersing N-GQDs In water, adding 3DOM In2O3,N2Bubbling for 1-3 h, then carrying out hydrothermal reaction on the mixture at the temperature of 150-180 ℃ for 4-8 h, naturally cooling to room temperature, and finally carrying out vacuum drying to obtain the N-GQDs modified 3DOM In2O3A composite material. Said composite material is in NO2The application of the gas sensor as a gas sensitive material. The 3DOM In modified by using N-GQDs In the invention2O3Effectively overcomes the defect that the two-dimensional graphene can not enter the 3DOM In2O3Inside the pore canal, thereby the problem of effective heterojunction can not be formed, the method has good repeatability, selectivity, long-term stability and short response recovery time, and can realizeActual detection concentration of 100 ppb, can be used for NO at ultra-low concentration2And (5) detecting the content.
Description
Technical Field
The invention belongs to the technical field of nano materials, and particularly relates to N-GQDsModified 3DOM In2O3Composite material and its preparation method and application.
Background
Nitrogen dioxide (NO)2) , the main component of air pollutants, is mainly derived from automobile exhaust and fossil fuel combustion, etc. research shows that long-term exposure to NO concentration over 1 ppm2In addition, it can form acid rain and contribute to the formation of ozone, which is major factors in photochemical smog formation, thus were developed to enable accurate, selective, rapid detection of NO2The resistance type metal oxide semiconductor gas sensor has attracted attention of people in recent years due to low cost, practicality, convenience and timely feedback, and as is well known, a three-dimensional ordered macroporous (3 DOM) material with a large specific surface area, high porosity and an open inner surface has more gas adsorption sites, is more beneficial to adsorption and desorption of gas, can increase the sensitivity of the sensor and shorten the response recovery time.
In2O3As kinds of wide band gap n-type semiconductors, has been widely used In the field of gas sensors due to their high conductivity and good chemical stability2O3The gas sensor still has the problems of high working temperature, low response value and the like, which limits the practical application of the gas sensor, therefore, 3DOM In with high porosity and large specific surface area are constructed2O3NO for high performance composites2Detection is very important.
The graphene serving as special carbon materials has the characteristics of large specific surface area, adjustable band gap, unique gas adsorption capacity and the like, and is proved to be excellent low-temperature NO2A sensing material. In addition, nitrogen doping in graphene can effectively increase NO2However, the single-phase graphene material is not beneficial to practical application due to long recovery time and poor selectivity in the gas sensing process, so that nitrogen doped materials are constructedHybrid graphene and 3DOM In2O3The heterojunction material is expected to realize NO with high response value, low working temperature and quick response-recovery time2And (4) gas sensing.
Disclosure of Invention
The invention aims to provide N-GQDs modified 3DOM In2O3Composite material and its preparation method and application.
In order to achieve the purpose, the technical scheme adopted by the invention is as follows:
N-GQDs modified 3DOM In2O3A composite material consisting of 3DOM In2O3(three-dimensionally ordered macroporous In)2O3) And N-GQDs (N-doped graphene quantum dots) uniformly loaded on the surface and in the pore channels.
The preparation method comprises the following steps: dispersing N-GQDs In water, adding 3DOM In2O3,N2Bubbling for 1-3 h, then carrying out hydrothermal reaction on the mixture at the temperature of 150-180 ℃ for 4-8 h, naturally cooling to room temperature, and finally carrying out vacuum drying to obtain the N-GQDs modified 3DOMIN2O3A composite material; wherein the dosage ratio of the raw materials is N-GQDs, water and 3DOM In2O3=(0.2~5) mg∶(5~20) mL∶(25~200) mg。
The 3DOM In modified by the N-GQDs2O3Composite material in NO2The application of the gas sensor as a gas sensitive material.
In the invention, 3DOM In2O3And N-GQDs can be prepared according to the prior art. NO according to the invention2Gas sensor made of Al2O3Ceramic tube coated with Al2O3N-GQDs modified 3DOM In on ceramic tube2O3The composite material, the nickel-cadmium heating wire and the hexagonal base. Al (Al)2O3The surface of the ceramic tube is provided with two parallel annular gold electrodes and four platinum wires for conducting electricity, and the nickel-cadmium heating wire is used for providing the required working temperature for the sensor. Wherein, Al2O3Structure of ceramic tube and structure for welding ceramic tube on hexagonal baseReference may be made to figure 1 of chinese patent CN 201710279627.9.
Has the advantages that:
1. 3DOM In modified by using N-GQDs2O3Effectively overcomes the defect that the two-dimensional graphene can not enter the 3DOM In2O3The inside of the pore channel can not form an effective heterojunction, and the method is not only suitable for 3DOM In2O3 can also be pushed to other 3DOM and other porous gas-sensitive material modifications;
2. by using a 3DOM In2O3N-GQDs are uniformly loaded on the surface and the inside of the pore channel, so that a large number of effective heterojunction interfaces are formed, and the NO is greatly improved2The response sensitivity of the sensor reduces the working temperature;
3. nitrogen is introduced into the graphene quantum dots, so that active sites of the material are increased, and NO is facilitated2The adsorption of (2) provides favorable conditions for subsequent reaction;
4. the obtained indirectly heated sensor has low working temperature, high sensitivity, good repeatability, selectivity, long-term stability and short response recovery time, can realize the actual detection concentration of 100 ppb, and can be used for NO under ultra-low concentration2Detecting the content; the indirectly heated sensor has the advantages of low price, simple process, small volume, portability, suitability for mass production and important practical value.
Drawings
FIG. 1: scanning electron micrographs of polystyrene microsphere templates and the products prepared in comparative example and example 3.
FIG. 2: transmission electron microscopy and high resolution transmission electron microscopy of the product prepared in example 3.
FIG. 3: products prepared in comparative and examples 1-5 were on 1 ppm NO2Response value versus operating temperature curve.
FIG. 4: comparative example and products prepared in examples 1-5 for different concentrations of NO at 100 deg.C2The dynamic response curve of (2).
FIG. 5: the product prepared in example 3 was aligned at 100 deg.C100 ppb~3 ppm NO2The response value of (2).
FIG. 6: the product prepared in example 3 is on 1 ppm NO at 100 deg.C2、50 ppm CO、50 ppm CH4、50 ppmNH3And 50 ppm formaldehyde.
FIG. 7: the product prepared in example 3 is resistant to 0.5 ppm NO at 100 deg.C2And 1 ppm NO2Long term stability test of (1).
Detailed Description
The following examples are given for the purpose of illustrating the invention in further detail and are not to be construed as limiting the invention in any way, and the materials used in the following examples, unless otherwise specified, are available from conventional chemical companies and suppliers of raw materials.
Example 1
N-GQDs modified 3DOM In2O3The preparation method of the composite material comprises the following steps:
(1) mixing 10 mg of graphene oxide (synthesized by an improved Hummers method) with 18 mL of secondary water and 2.0 mL of ammonia water (28wt%), carrying out ultrasonic treatment for 30 min, transferring the mixture into a reaction kettle with a polytetrafluoroethylene lining, carrying out solvothermal at 180 ℃ for 12h, naturally cooling to room temperature, filtering the mixed solution by using a 25nm microporous membrane to remove black precipitates, carrying out rotary evaporation and concentration on a golden yellow filtrate, carrying out purification in a 1000da dialysis bag for 1 day to remove excessive ammonia, and carrying out vacuum drying to obtain N-GQDs;
(2) synthesizing 3DOM In by an immersion-calcination method2O3The method comprises the following specific steps:
(2a) preparing a polystyrene microsphere template: 7.5 mL of purified styrene and 0.14 g K2S2O8Adding 200 mL of secondary water in N2Mechanically stirring at the speed of 6 rpm for 12 hours under protection, and centrifuging the polystyrene microsphere suspension at 1000 rpm for 24 hours after the reaction is finished to obtain a polystyrene microsphere template;
(2b) 3.82 g of In (NO)3)3·4.5H2O and 2.25 g of anhydrous citric acid are mixed in 5 mL of methanol and subjected to ultrasonic treatment for 30 min to prepare the compoundIn2O3A precursor solution; immersing polystyrene microsphere template into In2O3Vacuum filtering the precursor solution for 4 h to make the precursor solution enter the gaps of the polystyrene microsphere template; then excess precursor solution was removed by filtration and dried at 60 ℃ for 12h, the dried product being 1 ℃ min in a muffle furnace-1Heating to 550 ℃ at the heating rate, and keeping the temperature for 3 hours to obtain 3DOM In2O3;
(3) 0.2 mg of N-GQDs was dispersed In 10 mL of secondary water, and 100 mg of 3DOM In was added2O3,N2Bubbling for 2h, then pouring the mixture into a 25 mL reaction kettle, carrying out hydrothermal treatment at 150 ℃ for 4 h, naturally cooling to room temperature, and then carrying out vacuum drying at 60 ℃ to obtain the target product.
Example 2
The difference from example 1 is that: the N-GQDs in step (1) was 0.5 mg.
Example 3
The difference from example 1 is that: the N-GQDs in step (1) was 1.0 mg.
Example 4
The difference from example 1 is that: the N-GQDs in step (1) was 3.0 mg.
Example 5
The difference from example 1 is that: the N-GQDs in step (1) was 5.0 mg.
Comparative example
The difference from example 1 is that: no use of N-GQDs for 3DOM In2O3The modification was carried out by omitting step (3) In example 1, and the obtained product was 3DOM In2O3。
FIG. 1 is a scanning electron micrograph of a polystyrene microsphere template obtained in a comparative example, a product obtained in a comparative example, and a product obtained in example 3. As can be seen from fig. 1: the prepared polystyrene microsphere template is formed by arranging polystyrene microspheres with the diameter of 200 nm in a hexagonal way; the comparative example is a three-dimensional ordered macroporous structure with the pore diameter of about 130 nm, and the example 3 can still keep a good three-dimensional ordered macroporous structure after being modified by N-GQDs.
FIG. 2 shows TEM and TEM photographs of the product obtained in example 3. As can be seen from fig. 2: the uniform black dots In the white circles indicate that the N-GQDs are uniformly deposited In 3DOM In2O3A surface. Furthermore, In high resolution TEM, the lattice spacings of 0.292 nm and 0.253 nm correspond to 3DOM In2O3The (222) and (400) crystal planes of (A) and the lattice spacing of 0.214 nm corresponds to the (100) crystal plane of N-GQDs, this result further indicates that N-GQDs are successfully deposited In 3DOM In at step 2O3A surface.
Performance testing
The products prepared in examples 1 to 5 and comparative example were ground to powder in a mortar, and the powder and isopropyl alcohol were mixed to be pasty at a mass ratio of 0.5: 1.0, and then uniformly applied to commercially available Al with a brush pen2O3Coating sample on ceramic tube (with two parallel annular gold electrodes on its outer surface; two platinum wire leads from each gold electrode) to completely cover the two parallel gold electrodes, and coating Al2O3Drying the ceramic tube at 80 deg.C for 6 h, and passing nickel-cadmium heating wire through Al2O3Inside the ceramic tube, Al is added2O3And welding four platinum wires and nickel-cadmium heating wires on the ceramic tube on the side-heating hexagonal base to obtain the sensor.
Performance testing was performed using the resulting sensors. The gas sensitive test instrument is a Weisheng WS30A type gas sensitive element tester, and the test method is a static test method.
FIG. 3 is a graph of the product prepared in comparative example and examples 1-5 vs. 1 ppm NO2Response value versus operating temperature curve. As can be seen in fig. 3: after modification of N-GQDs, the working temperatures of the examples were all reduced from 160 ℃ to 100 ℃ as compared to the comparative examples, and the performance was improved, wherein example 3 was performed at 100 ℃ for 1 ppm NO2The response value of (a) was 82, which is 9.1 times that of the comparative example.
FIG. 4 shows the results of comparative examples and examples 1 to 5 at 100 ℃ for different concentrations of NO2The dynamic response curve of (2). As can be seen in fig. 4: at a different placeAll samples showed a fast recovery rate of response at concentration, indicating that the sample has good reproducibility, and example 3 shows different concentrations of NO2All showed the highest response value.
FIG. 5 shows that the product prepared in example 3 has 100 ppb-3 ppm NO at 100 ℃2The response value of (2). As can be seen from fig. 5: example 3 for different concentrations of NO2The response value of (2) shows substantially linear correlation, and furthermore, example 3 shows a linear correlation with respect to a low concentration of NO of 100 ppb2Still, a response value of 4.1 could be exhibited.
FIG. 6 shows the product of example 3 at 100 ℃ for 1 ppm NO2、50 ppm CO、50 ppm CH4、50ppm NH3And 50 ppm formaldehyde. As can be seen in fig. 6: example 3 for 1 ppm NO at 100 deg.C2Can reach 82, but has no response to other gas of 50 ppm.
FIG. 7 shows the results of example 3 at 100 ℃ for 0.5 ppm NO2And 1 ppm NO2Time-response plots for 60 days of continuous testing. As can be seen from FIG. 7, example 3 is on 0.5 ppm and 1 ppm NO in the test lasting 60 days2The response value of (a) is kept substantially constant and fluctuates only within a range of 7%. This result shows that example 3 is for NO2The sensing has better long-term stability.
Claims (3)
1, N-GQDs modified 3DOM In2O3A composite material characterized by: the composite material is composed of 3DOM In2O3And N-GQDs uniformly loaded on the surface and in the pore channels.
2, N-GQDs modified 3DOM In as claimed In claim 12O3The preparation method of the composite material is characterized by comprising the following steps: dispersing N-GQDs In water, adding 3DOM In2O3,N2Bubbling for 1-3 h, then carrying out hydrothermal reaction on the mixture at the temperature of 150-180 ℃ for 4-8 h, naturally cooling to room temperature, and finally carrying out vacuum drying to obtain the N-GQDs modified 3DOM In2O3A composite material; wherein the dosage ratio of the raw materials is N-GQDs, water and 3DOM In2O3=(0.2~5) mg∶(5~20) mL∶(25~200) mg。
3, N-GQDs modified 3DOM In as claimed In claim 12O3Composite material in NO2The application of the gas sensor as a gas sensitive material.
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