WO2011050516A1

WO2011050516A1 - Method of testing titania nanotubes for adsorbing-degrading performances on micro-interface thereof

Info

Publication number: WO2011050516A1
Application number: PCT/CN2009/074642
Authority: WO
Inventors: 陈军; 顾娟红; 卢艳光; 郑寿荣; 唐玉琼
Original assignee: Chen Jun; Gu Juanhong; Lu Yanguang; Zheng Shourong; Tang Yuqiong
Priority date: 2009-10-27
Filing date: 2009-10-27
Publication date: 2011-05-05

Abstract

A method of testing titania nanotubes for adsorbing-degrading performances on micro-interface thereof is characterized in that the method includes the following steps; (1) choosing a proper simulated contaminant, (2) synthesizing titania nanotubes and characterizing the same, (3) testing the titania nanotubes for adsorbing and photodegrading ratios of the simulated contaminant under different conditions. Testing titania nanotubes for methylene blue adsorbing and degrading performances can provide a mean for evaluating the qualities of nano-materials capable of imparting to products special functions, such as bacteria repellence, mildew proof, air purification, and surface self-cleaning.

Description

Adsorption-degradation performance determination method of titanium dioxide nanotube micro interface

The invention belongs to the technical field of product performance detection, and relates to a method for measuring photocatalytic ability of a micro interface of titanium dioxide nanotubes, and particularly relates to a simulated pollutant methylene blue which can effectively determine the photocatalytic effect of micro interface of titanium dioxide (Ti0 ₂ ) nanotubes. (MB) Method of adsorption-degradation performance. Background technique

As a semiconductor photocatalyst with excellent comprehensive performance, titanium dioxide (Ti0 ₂ ) nanomaterials have superior characteristics such as volume effect, surface effect, quantum size effect and macroscopic quantum tunneling due to the surface characteristics of their microstructure, especially titanium dioxide (Ti0 _{2 ).} The photocatalytic ability of nano-material micro-interface adsorption-degradation of organic pollutants has shown an attractive prospect in removing refractory pollutants in various environmental media. The use of nanotechnology has low energy consumption, simple operation and mild reaction conditions. The advantages of reducing secondary pollution, etc., can effectively completely inorganicize many toxic organic pollutants in the environment, and thus have attracted widespread attention and become a hot spot for development research.

The adsorption-degradation of the micro-interface of titanium dioxide (Ti0 ₂ ) nanomaterials is caused by the migration of photogenerated carriers to the micro-interface of the nanotubes, which is in full contact with the adsorbed water and oxygen on the surface to produce active hydroxyl radicals ( · OH ) and superoxide. Anionic free radicals preferentially degrade the pollutants adsorbed at the micro interface, making them harmless. Of course, the photochemical activity of the micro-interface of cerium oxide (Ti0 ₂ ) nanotubes can also be stimulated by the release of new eco-oxygen [0] due to its lattice defects and through the internal migration of the matrix material in contact with the surface of the nano-titanium dioxide (Ti0 ₂ ) material. The components react to form active groups such as active hydroxyl radicals and peroxyhydroxy radicals, which weaken the aging resistance of the matrix material and shorten the service life of the material. Therefore, how to integrate the micro-interface effect of nano-titanium dioxide (Ti0 ₂ ) materials with the improvement of the aging resistance requirements of the matrix materials is a problem that must be perfected when researching and developing application products.

The photoactivity of nano-titanium dioxide (Ti0 ₂ ) can be divided into photocatalytic action at the micro interface and photochemical reaction caused by self-lattice defects. Since the two generate different radicals, the action objects are different, so the effect of these free radicals In the photocatalytic process, free radicals are generated and act on the surface of the material, which has the function of sterilization and decontamination. In the photochemical active reaction process, free radicals are generated and act on the interior of the material, thus degrading the matrix material. , destructive effect. The adsorption-degradation performance of the nano-titanium dioxide (Τί0 ₂ ) micro-interface effect is mainly based on the effective utilization of its photocatalysis. In consideration of the action, the efficiency of the photocatalytic reaction was calculated by simulating the adsorption isotherm, photodegradation curve, degradation rate and kinetics of the pollutants, and the adsorption-degradation performance of the material was evaluated.

Through literature search, nano-titanium dioxide (Ti0 ₂ ) has been widely used in plastics and fiber masterbatch, leather, interior and exterior wall coatings, etc., giving the materials antibacterial, anti-mildew, air purification, surface self-cleaning, etc. Regarding the evaluation of its micro-interface adsorption-degradation performance, it is necessary to evaluate the micro-interface effect of nano-titanium dioxide (Ti0 ₂ ) directly bonded to the matrix material. Summary of the invention

The invention aims to provide a method for measuring the adsorption-degradation performance of a micro interface of titanium dioxide nanotubes, and solves the method for measuring the adsorption-degradation performance of the micro interface of the titanium dioxide nanotubes in the prior art and products, which results in failure to impart processing and processing energy. Problems such as performance and quality testing of nano-materials with special effects such as antibacterial, anti-mildew, air purification, and surface self-cleaning.

In order to solve the problems in the prior art, the technical solution provided by the present invention is:

A method for determining the adsorption-degradation performance of a micro interface of a titanium dioxide nanotube, characterized in that the method comprises the following steps:

(1) selecting suitable simulated pollutants;

(2) synthesizing titanium dioxide nanotubes and characterizing the synthesized titanium dioxide nanotubes;

(3) Determination of adsorption and photodegradation rate of simulated pollutants by titanium dioxide nanotubes under different conditions. Preferably, the simulated pollutant in step (1) of the method is selected from the group consisting of methylene blue.

Preferably, the synthesis of the titanium dioxide nanotubes in the method step (2) comprises the steps of forming a titanium dioxide nanotube precursor and the step of synthesizing the titanium dioxide nanotubes with the titanium dioxide nanotube precursor.

Preferably, the step of forming the titanium dioxide nanotube precursor in the step (2) of the method comprises: using titanium dioxide in the reaction vessel as an reaction medium, treating with a strong alkali, heating and dissolving, and cooling to form a crystal.

More preferably, the synthesis step of the titanium dioxide (Ti0 ₂ ) nanotube precursor comprises: adding 16 g of NaOH to 40 ml of distilled water, and after completely dissolving, taking Ti0 _{2 2} g, stirring at room temperature for 2 h, placed in an oven at 150 ° C, and heating for 5 hours, and taking out. After cooling, the resulting cake was chopped. Continue to heat in an oven at 150 °C for 10 h. The mixture was taken out and cooled, stirred well, and placed in a reaction vessel, and heated at 150 ° C for two days. After cooling, the lower part of the kettle is a relatively loose paste, and the supernatant is decanted to obtain dioxane. Titanium (Τί0 ₂ ) nanotube precursor.

Preferably, the step of synthesizing the titanium dioxide nanotubes in the titanium dioxide nanotube precursor in the method step (2) comprises pickling the titanium dioxide nanotube precursor to a pH of 6 to 6.5 and baking at different temperatures to form titanium dioxide having different properties. The steps of the nanotubes.

Preferably, the titanium dioxide (Ti0 ₂ ) nanotube is synthesized by placing a titanium dioxide (Ti0 ₂ ) nanotube precursor in a large beaker, adjusting the pH to 2.5, stirring, acid exchange for 2 h, washing to pH 6 to 6.5, 60 ° C. Dry in an oven. Titanium dioxide (Ti0 ₂ ) nanotubes dried at 60 degrees were calcined at different temperatures to obtain different types of titanium dioxide (Ti0 ₂ ) nanotubes. The firing conditions were as follows: The heating rate was 1 degree/minute, and calcined at 200 to 600 degrees for 5 hours.

Preferably, the method for characterizing the synthesized titanium dioxide nanotubes in the method step (2) comprises characterizing the titanium dioxide nanotubes by transmission electron microscopy, BET specific surface area, and X-ray diffraction.

Preferably, in the method step (2), the TiO 2 nanotubes having photocatalytic activity are characterized by a transmission electron microscope method, and the tube diameter is about 3 nm, and the tube wall is 3 to 4 layers.

Preferably, in the method step (2), the X-ray diffraction method is used to characterize the photocatalytic activity of the titanium dioxide nanotubes, and the nanotubes having a calcination temperature lower than 400 ° C are titanate type, and the nanotubes above 400 烧 are burned. Titanium dioxide anatase type.

Preferably, in the method step (3), the adsorption and photodegradation rate of the simulated pollutants by the titanium dioxide nanotubes under different conditions are determined, and the adsorption and photodegradation rates of the simulated contaminant methylene blue by the obtained titanium dioxide nanotubes at different calcination temperatures are determined.

In the step (3), the adsorption-degradation performance of the different types of titanium dioxide (T) ₂ nanotubes on the simulated pollutant methylene blue (MB) was evaluated by studying adsorption isotherms, photodegradation curves, degradation rates and kinetic studies. of. The adsorption isotherm of methylene blue (MB) on titanium dioxide (Ti0 ₂ ) nanotubes accords with the Langmuir adsorption model. Through the study of photodegradation curve and degradation rate, it is determined that the titanium dioxide (Ti0 ₂ ) nanotubes obtained at the calcination temperature of 400 Ό have the best adsorption-degradation effect on the simulated pollutant methylene blue (MB), and the degradation rate can reach 85%. The kinetic study of the present invention reflects that the photodegradation of the simulated pollutant methylene blue (MB) by titanium dioxide (Ti0 ₂ ) nanotubes is a comprehensive process, and is affected by both adsorption and surface photolysis processes. The cerium oxide (Ti0 ₂ ) nanotubes first adsorb the simulated contaminant methylene blue (MB) and then degrade on the surface.

The advantage of the present invention over the prior art solutions is - 1. The technical scheme of the present invention is characterized by transmission electron microscopy (TEM), BET specific surface area, X-ray diffraction (XRD), and adsorption isotherm of simulated pollutant methylene blue (MB) by studying different types of titanium dioxide (Ti02) nanotubes. Wire, photodegradation curve, degradation rate and kinetics study provide an effective method for evaluating the adsorption-degradation performance of titanium dioxide (Ti0 ₂ ) nanotubes, which is the decontamination ability of cerium oxide (Τί0 ₂ ) nanotube products. Technical support is provided for the standardization of evaluation methods.

2, a measuring method of the present invention can be best adsorbed titanium oxide (Ti0 and ₂₎ nanotubes - degradation by adsorption - the optimum conditions can be obtained titanium oxide (Ti0 and ₂₎ optimization of nanotubes of degradation. The titanium dioxide nanotubes synthesized by the method of the invention have good adsorption effect on methylene blue, and can effectively inhibit the migration of dyes; the nanotubes have good photodegradation effect on methylene blue under the experimental conditions. In the actual fabric and environmental water, the nanotubes will effectively degrade various pollutants and achieve purification.

In summary, the present invention provides a method for evaluating the micro-interface properties of nano-titanium dioxide (Ti0 ₂ ) based on the exploration product, and the nanotube precursor is prepared by using titanium dioxide (Ti0 ₂ ), pickling and drying at different temperatures. The sub-step calcination was carried out to obtain different titania (Ti0 ₂ ) nanotubes, which were characterized by transmission electron microscopy (TEM), BET specific surface area, X-ray diffraction (XRD), and methylene blue by titanium dioxide (Ti0 ₂ ) nanotubes. MB) Adsorption-degradation performance evaluation, providing technical support for the standardization of evaluation methods. DRAWINGS

The present invention is further described below in conjunction with the accompanying drawings and embodiments:

Figure 1 is a transmission electron microscope (TEM) FIG titania (Ti0 and ₂₎ nanotubes pickling and drying 60 ° C; FIG. 2 is a transmission titania (Ti0 and ₂₎ pickling nanotubes drying 60 ° C 300 ° C calcination Electron microscopy (TEM) image;

Figure 3 is a transmission electron microscope (TEM) image of titanium dioxide (Ti0 ₂ ) nanotubes after baking at 500 ° C for 500 C baking;

4 is calcined at different temperatures titania X-ray diffraction (Ti0 ₂₎ nanotubes (XRD) pattern; FIG. 5 is a different firing temperature of titanium dioxide (Ti0 ₂₎ nanotubes to blue light degradation methylene curve; FIG. 6 is a different firing temperature of titanium dioxide (Ti0 ₂ ) the degradation rate of nanotubes to the simulated pollutant methylene blue (MB);

Figure 7 shows the simulated contaminant methylene blue (MB) in titanium dioxide (Ti0 ₂ ) at different calcination temperatures. Adsorption isotherms on nanotubes. detailed description

The above scheme will be further described below in conjunction with specific embodiments. It is to be understood that the examples are intended to illustrate the invention and not to limit the scope of the invention. The implementation conditions employed in the examples can be further adjusted according to the conditions of the specific manufacturer, and the unspecified implementation conditions are usually the conditions in the conventional experiment.

Determination of Micro-interface Adsorption-Degradation Performance of Simulated Contaminant Methylene Blue (MB) by Titanium Dioxide (Ti0 ₂ ) Nanotubes

(1) Synthesis of titanium dioxide (Ti0 ₂ ) nanotubes

Instruments and reagents:

Philips Tecnai-12 transmission electron microscope (HRTEM); D/max-RA type X-ray diffractometer (RigaKu ^TM , JP); Cary 5000 UV-VIS spectrophotometer (Varian ^TM , USA); sodium hydroxide (NaOH) ) (AR) _; titanium dioxide (Τί0 ₂ ) and the like.

Measuring condition

X-ray diffraction (XRD) measurement conditions: Starting angle: 5; End angle: 70; Step size: 0.02; Scanning speed: 10; Integration time: 0.1; Target type: Cu; Tube pressure: 50 Kvl 50 mA; 1, 1, 0.6, 0.6; Filter: Graphite. UV-Vis spectrophotometer measured wavelength: 665 nm.

Synthesis step

Synthesis of Titanium Dioxide (Ti0 ₂ ) Nanotube Precursor 16 g of NaOH was added to 40 ml of distilled water. After completely dissolving, Ti0 ₂ 2 _{g was taken} , stirred at room temperature for 2 h, placed in an oven at 150 ° C, and heated for 5 h before being taken out. After cooling, the resulting cake was chopped. Continue to heat in an oven at 150 °C for 10 h. Take out the cooling, stir and hook, continue to put in the reaction kettle, and heat at 150 °C for two days. After cooling, the lower part of the kettle was a relatively loose paste, and the supernatant was decanted to obtain a titanium dioxide (Ti0 ₂ ) nanotube precursor.

Synthesis of titania (Ti0 ₂₎ of titanium dioxide nanotubes (Ti0 ₂₎ nanotube precursor in a large beaker, pH was adjusted to 2.5, with stirring, nucleotide exchange 2H; until the pH was 6~6.5, 60Ό drying oven. The 60-degree dried nanotubes are calcined at different temperatures to obtain catalysts of different properties. The baking conditions were as follows: the heating rate was 1 degree/minute, and the firing was performed at 200 to 600 degrees for 5 hours.

(2) Characterizing titanium dioxide (Τί0 ₂ ) nanotubes

Transmission electron microscope (ΤΕΜ) It can be seen from the TEM image that the tube diameter is about 1 nm, which is nanometer, and the wall is 3 to 4 layers.

BET specific surface area

Table 1 BET specific surface area calcination temperature of titanium dioxide (Ti0 ₂ ) nanotubes at different calcination temperatures / ° c Unbaked 200 300 350 400 500 600 700 specific surface area / m ² * gl 263.5 250.0 256.1 284.9 193.8 83.8 53.5 22.6 The data in the table shows The relationship between the BET specific surface area of the titanium dioxide (Ti0 ₂ ) nanotubes and the calcination temperature is basically that the specific surface area decreases as the calcination temperature increases, which is more remarkable in the high temperature region. In addition, the raw material titanium dioxide is processed to form a nanotube, and its BET specific surface area is relatively increased (the Ti0 ₂ specific surface area of the raw material is less than 10 m ² , gl ). The increase in specific surface area will be more effective for the adsorption of dye molecules.

X-ray diffraction (XRD)

Figure 2 shows, the firing temperature is lower than 400 Ό titanium oxide (Ti0 and ₂₎ titanate nanotubes type, above 400 ° C titanium dioxide (Ti0 and ₂₎ nanotube anatase, 400 ° C is titanium dioxide (Ti0 and ₂ ) The crystallographic point of the nanotube.

(3) Adsorption-degradation of simulated pollutant methylene blue (MB) by different types of titanium dioxide (Ti0 ₂ ) nanotubes

1) The adsorption isotherm of titanium dioxide (Ti0 ₂ ) nanotubes on the simulated pollutant methylene blue (MB) can be seen from Figure 7. The adsorption isotherm of the simulated pollutant methylene blue (MB) on the titanium dioxide (Τί0 ₂ ) nanotubes is consistent with Langmuir. The adsorption model, that is, the adsorption of the simulated pollutant methylene blue (MB) by titanium dioxide (Ti0 ₂ ) nanotubes reaches saturation at a low concentration, and then the saturated adsorption amount of methylene blue (MB) is basically unchanged as the equilibrium concentration increases. The 300 'C calcined titanium dioxide (Ti0 ₂ ) nanotubes had a saturated adsorption capacity for methylene blue (MB) of 130 mg/g.

It can also be seen from the figure that the saturated adsorption amount of methylene blue (MB) on titanium dioxide (Ti0 ₂ ) nanotubes increases with increasing temperature at lower calcination temperature range; at higher calcination temperature range, with calcination temperature The increase in the amount of methylene blue (MB) adsorbed by titanium dioxide (Ti0 ₂ ) nanotubes is significantly reduced. Except that no calcination of titanium dioxide (Ti0 ₂₎ nanotube, methylene blue other firing temperature (Ti0 ₂₎ nanotubes of titanium dioxide (MB) adsorption amount table BET specific surface area data has a good correlation, i.e., titanium dioxide (Τί0 ₂₎ The larger the specific surface area of the nanotube, the larger the amount of methylene blue (MB) adsorbed.

2) Photodegradation of simulated contaminant methylene blue (MB) by titanium dioxide (Ti0 ₂ ) nanotubes The initial concentration of the simulated contaminant methylene blue (MB) was 83 mg/L. Figure 5 shows that the titanium dioxide (Ti0 ₂ ) nanotubes obtained at 400 °C calcination have the best degradation effect on the simulated pollutant methylene blue (MB), and the degradation rate can reach 85%, indicating that the titanium dioxide (Ti0 ₂ ) nanotubes are used as a simulation. The effectiveness of the photodegradable medium of the contaminant methylene blue (MB).

3) Kinetics of degradation of methylene blue (MB) by simulated titanium dioxide (Ti02) nanotubes Photodynamic degradation of nanotubes at three calcination temperatures Kinetic data of MB Calcination temperature / °c 300 °C 400 °C 500 °C

Speed constant 0.36 1.93 2.38

Adsorption constant 1.16 0.45 0.08

From the table combined with the above adsorption map and photodegradation map, it is reflected that the photodegradation of titanium dioxide (Ti0 ₂ ) nanotubes as a simulated pollutant methylene blue (MB) is a comprehensive process, which is affected by both adsorption and surface photolysis. The titanium dioxide (Ti0 ₂ ) nanotubes first adsorbed the surface of the simulated pollutant methylene blue (MB) and degraded on the surface. The larger the specific surface area of the titanium dioxide (Ti0 ₂ ) nanotubes and the more uniform the pore distribution, the larger the adsorption amount of the simulated pollutant methylene blue (MB) in the first step; and the titanium dioxide (Ti0 ₂ ) nanometer obtained by calcining more than 400 Ό. The tube is anatase crystal form, and the degradation of contaminants by anatase is more effective than other crystal forms. Table 2 also reflects that the higher the proportion of titanium dioxide (1 0 ₂ ) nanotube anatase crystal form, the simulated pollutants The photodegradation rate constant of methylene blue (MB) is larger. The comprehensive evaluation showed that the adsorption-degradation evaluation of the micro-interface effect of titanium dioxide (Ti0 ₂ ) nanotubes using methylene blue (MB) as a simulated pollutant was effective, and anatase-type nanotube titanium dioxide (Ti0 ₂ ) nanotube pairs were also found. The simulated pollutant methylene blue (MB) has the best degradation efficiency, up to 85%.

In this embodiment, the adsorption-degradation of the widely used titanium dioxide (Ti0 ₂ ) nanomaterials by using methylene blue (MB) as a simulated pollutant is studied, and the nanotube precursor is prepared by titanium dioxide (Τί0 ₂ ), pickled and baked. After drying, the calcination was carried out at different temperatures to obtain different titania (Ti0 ₂ ) nanotubes, which were characterized by transmission electron microscopy (TEM), BET specific surface area and X-ray diffraction (XRD), and passed through titanium dioxide (Ti0 ₂ ). The adsorption isotherms, photodegradation curves, degradation rates and kinetics of the simulated pollutant methylene blue (MB) were calculated by nanotubes. The degradation rate of the photocatalytic reaction of the dye methylene blue (MB) was calculated to evaluate the adsorption and photodegradation of the material. performance.

The titanium dioxide (Ti0 ₂ ) nanotubes used in the experiment have a good adsorption effect on the simulated pollutant methylene blue (MB), and the highest adsorption capacity can reach 130 mg/g. The titanium dioxide (Ti0 ₂ ) nanotubes under the experimental conditions simulate the pollutant methylene blue ( MB) has good photodegradation and the highest degradation rate is 85%. Studies have shown that the adsorption-degradation performance evaluation of the micro-interface effect of titanium dioxide (Ti0 ₂ ) nanomaterials on the simulated pollutant methylene blue (MB) can be applied to the production process to impart antibacterial, anti-mildew, air purification and surface self-cleaning. The evaluation of the performance and quality of nano-materials with special effects is conducive to providing corresponding technical support for further improving the standards of nano-product technology.

The above examples are only intended to illustrate the technical concept and the features of the present invention, and the purpose of the present invention is to enable those skilled in the art to understand the present invention and to implement the present invention, and the scope of the present invention is not limited thereto. Equivalent transformations or modifications made in accordance with the spirit of the invention are intended to be included within the scope of the invention.

Claims

1 - A method for determining the adsorption-degradation performance of a micro interface of a titanium dioxide nanotube, characterized in that the method comprises the following steps:

(1) selecting suitable simulated pollutants;

(3) Determination of adsorption and photodegradation rate of simulated pollutants by titanium dioxide nanotubes under different conditions.

2. A method according to claim 1 wherein the simulated contaminant in step (1) of the method is selected from the group consisting of methylene blue.

The method according to claim 1, characterized in that the synthesis of the titanium dioxide nanotubes in the method step (2) comprises the steps of forming a titanium dioxide nanotube precursor and synthesizing the titanium dioxide nanotubes with the titanium dioxide nanotube precursor.

4. The method according to claim 3, wherein the step of forming the titanium dioxide nanotube precursor in the step (2) of the method comprises: using titanium dioxide in the reaction vessel as an reaction medium, treating with a strong alkali, heating and dissolving, Cooling crystal formation.

5. The method according to claim 3, wherein the step of synthesizing the titanium dioxide nanotubes in the titanium dioxide nanotube precursor in the method step (2) comprises pickling the titanium dioxide nanotube precursor to a pH of 6 to 6.5. The step of firing to form titanium dioxide nanotubes of different properties under different temperature conditions.

6. The method according to claim 1, wherein the method for characterizing the synthesized titanium dioxide nanotubes in the method step (2) comprises using a transmission electron microscope, a BE T specific surface area, and an X-ray diffraction method for the titanium dioxide nanotubes. Characterize.

7. The method according to claim 6, characterized in that in the method step (2), the diameter of the titanium dioxide nanotubes having photocatalytic activity is about lOnm and the walls of the tubes are 3 to 4 layers by means of transmission electron microscopy.

8. The method according to claim 6, characterized in that in the method step (2), the photocatalytic activity of the ceria nanotubes having a photocatalytic activity at a calcination temperature of less than 400 Å is determined by an X-ray diffraction method. Type, the nanotubes above 400 烧 are burnt to the titanium dioxide anatase type.

9. The method according to claim 6, characterized in that in the method step (3), the adsorption and photodegradation rate of the simulated pollutants by the ceria nanotubes under different conditions are determined, and the obtained titanium dioxide nanometers at different calcination temperatures are determined. The adsorption and photodegradation rate of the simulated pollutant methylene blue.