KR101164000B1 - Hybrid nanostructure thin film type photocatalyst - Google Patents

Abstract

The present invention relates to an ultraviolet ray and a visible photocatalyst comprising a hybrid carbon-titanium dioxide nanostructure thin film or a silver-titanium dioxide nanostructure thin film and a method for preparing the hybrid nanostructure thin film according to the present invention. When the titanium dioxide sol-gel precursor solution is mixed with each other, their relative mixing ratios can be adjusted to control the shape and arrangement of the structures, and the carbon nanostructures can be used to form nanostructures without using precursors or activation catalysts for carbon production. The hybrid carbon-titanium dioxide nanostructure thin film or the hybrid silver-titanium dioxide nanostructure thin film produced can be easily used as an ultraviolet light and visible light catalyst because it shows enhanced activity as an ultraviolet light and visible light catalyst. Eco-friendly cattle , It may be useful in various fields, such as the energy element and the electrode element.

Description

Hybrid nanostructure thin film type photocatalyst

The present invention relates to ultraviolet and visible photocatalysts comprising hybrid nanostructure thin films.

Carbon-containing materials have a wide range of applications as catalysts or energy storage because of their excellent mechanical strength, chemical stability, and freely adjustable structure. Common carbon nanostructures represented by carbon nanotubes (CNTs), graphene, fullerenes, etc. have recently been used as catalyst chemical vapor deposition (CVD), Catalytic pyrolysis, high-temperature hydrothermal conversion, replication of shape-providing hard templates such as silica, etc. Has been prepared. In particular, hybrid carbon nanomaterials, in which metals, ceramics, polymer materials, etc. are bonded to carbon materials, contain carbon, which serves as a reinforcing material, in addition to the properties of the combined materials. Therefore, corrosion resistance, fatigue resistance, dimensional stability, etc. Function is granted. Therefore, this composite material has excellent thermal stability, mechanical properties, chemical resistance, radiation resistance, thermal conductivity, and electrical conductivity, compared to other materials, and thus is suitable for applications such as high-temperature structures such as aerospace bodies, high-temperature furnaces for the manufacture of semiconductors, and defense industries. It has been used intensively, and the market has been gradually expanded to general industrial use.

However, the conventional carbon material manufacturing method as described above is required to additionally introduce a carbon precursor, it is not advantageous in terms of economics because the use of an activation catalyst in the process, or most of the complex multi-step process is adopted. In addition, when producing the multi-component particles, the uniformity of the components in the particles are lowered, it is difficult to control in the form of the particles. On the other hand, in recent years, a study on a method for producing a carbonaceous material using a block copolymer (BCP) as a soft template (soft template) has been conducted. This is because the degree of freedom in terms of structure control is higher than that of the above methods, which used a hard material as a template, and by selectively introducing a carbon precursor into a desired block, nanospheres and nanotubes having characteristic structures nanotubes, nanorods, nanoporous thin films and the like can be fabricated.

On the other hand, titanium dioxide is one of the representative semiconductor materials used as a photocatalyst. In general, a photocatalyst refers to a catalyst that plays a role of decomposing surrounding pollutants by oxidizing / reducing a reaction by receiving light energy, that is, a catalyst that increases the photoreaction rate using light. Titanium dioxide is frequently used because it is relatively inexpensive compared to other materials, has excellent durability as a photocatalyst, and is a non-toxic material having excellent stability and thus does not cause pollution during disposal. On the other hand, semiconductor materials such as titanium dioxide have an energy band structure. The highest energy band occupied by electrons among the energy bands of a semiconductor is called a valence band, and the lowest energy band not occupied by electrons is a conduction band. Their energy difference is called band gap energy, which is unique for each material. When irradiating light with energy larger than the band gap energy inherent in such semiconductor materials, electrons are excited in the valence band and are transferred to the conduction band, and holes are formed in the valence band, and these electron-hole pairs Harmful oxidation and reduction reactions caused by the decomposition of harmful substances around. The energy band gap in the semiconductor material prevents the rapid recombination of electrons and holes induced in the valence band and conduction band, thereby extending the duration of the photochemical redox reaction. However, semiconductors with a large band gap (3.2 eV), such as titanium dioxide, have a property of absorbing only light having a short wavelength in a range of less than 400 nm. .

In order to make up for such drawbacks, studies have recently been actively conducted to hybridize materials of different components to titanium dioxide. By introducing precious metal nanoparticles into mono-component titanium dioxide, it has improved photocatalytic activity due to the induction effect of surface plasmon properties of these components, or hybridizes semiconductor materials such as silicon dioxide with a smaller band gap than titanium dioxide. There is a frequent attempt to expand the absorbance to the visible light range, but there is a difficulty in producing a titanium dioxide catalyst extended to the visible light range, there is still a need for a material having improved photocatalytic activity.

Accordingly, the present inventors have studied to prepare a material having improved photocatalytic activity to improve the limitation of monocomponent titanium dioxide as a photocatalyst, while carbonizing a self-assembled biblock copolymer and a sol-gel process and a diblock copolymer nanotemplate. The present invention was completed by simply preparing a hybrid carbon-titanium dioxide nanostructure thin film or hybrid silver-titanium dioxide nanostructure thin film using the process and confirming enhanced activity as an ultraviolet and visible light catalyst.

An object of the present invention to provide an ultraviolet and visible photocatalyst comprising a hybrid nanostructure thin film.

In order to achieve the above object, the present invention provides an ultraviolet and visible photocatalyst comprising a hybrid carbon-titanium dioxide nanostructure thin film or silver-titanium dioxide nanostructure thin film.

In addition, the present invention comprises the steps of dissolving the amphiphilic diblock copolymer in a solvent to prepare a reverse micelle solution (step 1); Dissolving the titanium dioxide precursor in a solvent to prepare a titanium dioxide sol-gel precursor solution (step 2); Mixing the reverse micelle solution prepared in step 1 with the sol-gel precursor solution prepared in step 2 and spin-coating the substrate to prepare a titanium dioxide-diblock copolymer thin film (step 3); And carbonizing or removing the biblock copolymer (step 4) by irradiating UV light on the thin film prepared in step 3 and then heat treating the thin film of the hybrid carbon-titanium dioxide nanostructure.

Furthermore, the present invention comprises the steps of dissolving the amphiphilic diblock copolymer in a solvent to prepare a reverse micelle solution (step A);

Dissolving the titanium dioxide precursor in a solvent to prepare a titanium dioxide sol-gel precursor solution (step B);

Dissolving the silver nanoparticle precursor in a solvent to prepare a silver nitrate solution (step C);

The reverse micelle solution prepared in step A, the sol-gel precursor solution prepared in step B, and the silver nitrate solution prepared in step C were mixed and spin-coated to a substrate to form a silver / titanium dioxide-diblock copolymer thin film. Manufacturing step (step D); And

It provides a method for producing the hybrid silver-titanium dioxide nanostructure thin film comprising the step (step E) of irradiating ultraviolet light to the thin film prepared in step D to remove the diblock copolymer.

In the method for preparing a hybrid nanostructure thin film according to the present invention, when the diblock copolymer and the titanium dioxide sol-gel precursor solution are mixed, the shape and arrangement of the structures can be controlled by changing their relative mixing ratios, and a carbonization process is performed. Thus, nanostructures can be easily prepared without using precursors or activation catalysts for the production of carbon, and the prepared hybrid carbon-titanium dioxide nanostructure thin films or hybrid silver-titanium dioxide nanostructure thin films have enhanced activity as ultraviolet and visible light catalysts. Since it can be usefully used as an ultraviolet and visible light catalyst, it can be usefully used in various fields such as environmentally friendly devices, energy devices and electrode devices using the same.

1 is a schematic view showing a method of manufacturing a hybrid nanostructure thin film according to an embodiment of the present invention;
FIG. 2 is an atomic force microscope (AFM) photograph showing the surface morphology of a hybrid nanostructure thin film prepared by a manufacturing method according to an embodiment of the present invention; FIG.
3 is a graph showing a result of analyzing a hybrid nanostructure thin film manufactured by a manufacturing method according to an embodiment of the present invention with a Raman spectrometer;
4 is a high-resolution transmission electron microscope (HRTEM, JEOL, Japan) and an energy dispersive X-ray spectrometer (EDX, JEOL, Japan) to investigate the internal structure of the hybrid nanostructure thin film manufactured by the manufacturing method according to the present invention Photographs and graphs showing the results of the analysis;
5 is an atomic force microscope (AFM), high resolution transmission electron microscope (HRTEM) and energy dispersive X-ray spectroscopy to investigate the surface shape and internal structure of a hybrid nanostructure thin film manufactured by a manufacturing method according to an embodiment of the present invention. Photographs and graphs showing results of analysis with (EDX);
Figure 6 is a graph measuring the photocatalytic activity by ultraviolet light of the hybrid nanostructure thin film (Example 1 and Example 2) prepared by the manufacturing method according to an embodiment of the present invention;
7 is a graph measuring photocatalytic activity by ultraviolet rays of a hybrid nanostructure thin film (Examples 3 and 4) prepared by a manufacturing method according to an embodiment of the present invention; And
8 is a graph measuring photocatalytic activity by visible light of a hybrid nanostructure thin film (Examples 1 and 2) prepared by a manufacturing method according to an embodiment of the present invention.

The present invention provides an ultraviolet and visible light photocatalyst comprising a hybrid nanostructure thin film.

In the photocatalyst according to the present invention, the hybrid nanostructure is formed in a hybrid carbon-titanium dioxide nanostructure or a titanium dioxide matrix formed by arranging carbon nanopoints in a titanium dioxide matrix, or in which a titanium dioxide nanopoints are arranged in a carbon matrix. Hybrid silver-titanium dioxide nanostructures formed by arranging silver nanodots may be used, but are not limited thereto.

The hybrid nanostructure may control the shape and arrangement of the structure according to the mixing ratio of the reverse micelle solution in which the amphiphilic diblock copolymer is dissolved, the titanium dioxide sol-gel precursor solution, and optionally the silver nitrate solution.

For example, hybrid carbon-titanium dioxide nanostructures formed by arranging carbon nanodots within a titanium dioxide matrix are known as titanium dioxide sol-gel precursors to reverse micelle solutions in which amphiphilic diblock copolymers are dissolved in 1,4-dioxane. The solution may be prepared by spin coating the substrate at 38-50 wt%, followed by irradiation with ultraviolet rays and heat treatment, and in the case of hybrid carbon-titanium dioxide nanostructures formed by arranging titanium dioxide nanopoints in a carbon matrix. It can be prepared by mixing the titanium dioxide sol-gel precursor solution in an amount of 8-12 wt% with respect to the reverse micelle solution in which the diblock copolymer is dissolved in toluene, spin-coating the substrate, and then irradiating and heat-treating ultraviolet rays.

In addition, the hybrid silver-titanium dioxide nanostructure formed by arranging silver nanopoints in the titanium dioxide matrix is prepared by using a titanium dioxide sol-gel precursor solution with respect to a reverse micelle solution in which an amphiphilic diblock copolymer is dissolved in 1,4-dioxane. 38-50% by weight, and the silver nitrate solution in which the silver nanoparticle precursor was dissolved in the solvent was mixed so that the silver particles were 0.1-0.7 molar ratio (Ag / EO) to the ethylene oxide in the reverse micelle solution and spin-coated to the substrate. And then irradiated with ultraviolet light.

In the photocatalyst according to the present invention, the hybrid carbon-titanium dioxide nanostructure thin film

Dissolving the amphiphilic diblock copolymer in a solvent to prepare a reverse micelle solution (step 1);

Dissolving the titanium dioxide precursor in a solvent to prepare a titanium dioxide sol-gel precursor solution (step 2);

Mixing the reverse micelle solution prepared in step 1 with the sol-gel precursor solution prepared in step 2 and spin-coating the substrate to prepare a titanium dioxide-diblock copolymer thin film (step 3); And

The thin film prepared in step 3 may be prepared by a method including a step (step 4) of carbonizing or removing the diblock copolymer by irradiating ultraviolet rays with heat treatment.

Hereinafter, a method of manufacturing a hybrid carbon-titanium dioxide nanostructure thin film according to the present invention will be described in detail step by step (see FIG. 1).

Step 1 is a step of preparing a reverse micelle solution by dissolving the amphiphilic diblock copolymer in a solvent.

The amphiphilic diblock copolymer of step 1 allows reverse micelles to be formed in a solution using a solvent that selectively dissolves only one block, and the amphiphilic diblock copolymer is poly (styrene-block-ethylene oxide) ( Poly (styrene-b-ethylene oxide), PS-b-PEO) can be used.

In addition, the solvent of step 1 may be used 1,4-dioxane, toluene and the like.

In this case, in the hybrid carbon-titanium dioxide nanostructure thin film, when the titanium dioxide is manufactured as a nano dot, it is preferable to use toluene that can selectively dissolve the polystyrene block in the amphiphilic diblock copolymer. When titanium is prepared as a mesoporous structure, it is preferable to use 1,4-dioxane having a similar affinity for both the polystyrene block and the polyethylene oxide block in the amphiphilic diblock copolymer.

Furthermore, the reverse micelle solution of Step 1 preferably contains 0.1-1 wt% of amphiphilic diblock copolymer. If the amphiphilic diblock copolymer is less than 0.1% by weight, there is a problem in that a single molecule film without defects of uniform density may not be formed during thin film manufacturing by spin coating, and when the amount exceeds 1% by weight, a multilayer film is formed. There is a problem.

Next, step 2 is a step of dissolving the titanium dioxide precursor in a solvent to prepare a titanium dioxide sol-gel precursor solution.

In step 2, the titanium dioxide sol-gel precursor solution may be prepared by dissolving the titanium dioxide precursor in a solvent, diluting by adding a strong acid, and stirring. At this time, it is preferable to use concentrated hydrochloric acid and acetic acid as the strong acid, and more preferably to use concentrated hydrochloric acid, but is not limited thereto as long as it is a solvent capable of preparing the titanium dioxide sol-gel precursor solution. The strong acid may open or recess the polyethylene oxide block portion of the amphiphilic diblock copolymer of step 1, and hydrolyze the titanium dioxide precursor to form dense titanium dioxide nanoparticles in the open or recessed polyethylene oxide portion. Make sure

In addition, in the step 2, the titanium dioxide precursor may use titanium tetra-isopropoxide, titanium tetrabutoxide, titanium alkoxide, and the like, and the solvent may be ethanol, Isopropanol and the like can be used.

Next, step 3 is a step of preparing a titanium dioxide-diblock copolymer thin film by mixing the reverse micelle solution prepared in step 1 and the sol-gel precursor solution prepared in step 2 and spin-coating the substrate.

In the step 3, the mixing ratio of the hybrid carbon-titanium dioxide nanostructure thin film, in which the titanium dioxide sol-gel precursor solution is mixed in an amount of 8-12 wt% with respect to the reverse micelle solution when the titanium dioxide is formed as a nano dot It is preferable. If the titanium dioxide sol-gel precursor solution is mixed at less than 8% by weight, there is a problem in that the amount of the sol-gel precursor solution that forms the nanopoint is not sufficient to form a uniform nanopoint array. In the case where the weight percentage exceeds the sol, the sol-gel precursor residues are agglomerated with each other, and thus, the previously formed nanopoints are bonded to each other to maintain the nanopoints in a constant size and distribution.

In addition, in the hybrid carbon-titanium dioxide nanostructure thin film, when the carbon is formed as a nano dot, it is preferable to mix the titanium dioxide sol-gel precursor solution with 38-50 wt% with respect to the reverse micelle solution. If the titanium dioxide sol-gel precursor solution is less than 38% by weight, there is a problem that carbon nanopoints are not formed due to insufficient amount of the precursor, and when the amount exceeds 50% by weight, the sol-gel precursor solution residue is a polystyrene block. There is a problem in that the carbon nano point is not formed by combining with.

In addition, the spin coating in step 3 is preferably performed at a speed of 2000-3000 rpm. If the spin coating is less than 2000 rpm, there is a problem in that the nanoparticles are formed into a multilayer film, and if the spin coating is more than 3000 rpm, there is a problem in that the mono-molecule film of uniform thickness and density cannot be produced.

Next, step 4 is a step of carbonizing or removing the diblock copolymer by irradiating ultraviolet rays to the thin film prepared in step 3 and then heat treatment.

The polymer of the monomolecular film prepared in step 3 is a nanopattern induced form by self-assembly of the biblock copolymer. The heat treatment of the diblock copolymer is performed in a high temperature environment. In order to maintain the nanopattern of the structure, it is preferable to perform a process of stabilizing the pattern before heat treatment. In order to maintain the nanopattern of the structure, the cured thin film of the form in which the nanopattern is maintained can be prepared by irradiating ultraviolet rays of 254 nm wavelength at 50 to 70 minutes at 20-30 W / cm 2 energy intensity in a vacuum state.

In step 4, the heat treatment is preferably carried out at 550-650 ℃ 50-70 minutes in an argon atmosphere. The polystyrene block cured through the heat treatment is changed to a pure carbon component and the polyethylene oxide block is removed.

Further, in the photocatalyst according to the present invention, the hybrid silver-titanium dioxide nanostructure thin film

Dissolving the amphiphilic diblock copolymer in a solvent to prepare a reverse micelle solution (step A);

Dissolving the titanium dioxide precursor in a solvent to prepare a titanium dioxide sol-gel precursor solution (step B);

Dissolving the silver nanoparticle precursor in a solvent to prepare a silver nitrate solution (step C);

The reverse micelle solution prepared in step A, the sol-gel precursor solution prepared in step B, and the silver nitrate solution prepared in step C were mixed and spin-coated to a substrate to form a silver / titanium dioxide-diblock copolymer thin film. Manufacturing step (step D); And

Irradiating the thin film prepared in step D may be prepared by a method comprising the step of removing the diblock copolymer (step E).

In this case, steps A and B may be performed in the same manner as steps 1 and 2 according to the present invention, and the silver nitrate solution of step C may be prepared by dissolving a silver nanoparticle precursor in a solvent.

In the step D, the titanium dioxide sol-gel precursor solution is preferably mixed in an amount of 38 to 50 wt% based on the reverse micelle solution, and the silver nitrate solution contains 0.1 to 0.7 molar ratio of silver particles to the ethylene oxide in the reverse micelle solution (Ag / It is preferable to mix so that it becomes EO). If the molar ratio of the silver particles is less than 0.1, there is a problem that the silver particles are not uniformly dispersed in the reverse micelles, and when the molar ratio exceeds 0.7, the silver particles are not included in the reverse micelles, and the silver particles are combined to form agglomerates. there is a problem. The silver nanoparticle precursor may use a material having hydrophilicity such as silver nitrate and silver acetate, and the solvent may be isopropanol, ethanol, methanol, or the like.

Steps D and E may be carried out in the same manner as steps 3 and 4 according to the present invention, except for the above-described contents, to prepare a hybrid nanostructure thin film.

In the method for preparing a hybrid nanostructure thin film according to the present invention, when the diblock copolymer and the titanium dioxide sol-gel precursor solution are mixed, the shape and arrangement of the structures can be controlled by changing their relative mixing ratios, and a carbonization process is performed. Thus, nanostructures can be easily prepared without using precursors or activation catalysts for the production of carbon.

In addition, the hybrid carbon-titanium dioxide nanostructure thin film or the hybrid silver-titanium dioxide nanostructure thin film prepared by the above method significantly reduces the absorbance of methylene blue or para-nitrophenol solution as a result of measuring photocatalytic activity by ultraviolet light and visible light. It can be usefully used as an ultraviolet and visible light catalyst because it shows improved activity as a catalyst by decreasing.

Hereinafter, the present invention will be described in more detail by way of examples. It should be noted, however, that the following examples are illustrative of the invention and are not intended to limit the scope of the invention.

< Example  1> hybrid  Preparation of carbon-titanium dioxide nanostructure thin film 1

Step 1: Reverse mice  Step of preparing a solution

1.0 weight of poly (styrene-block-ethylene oxide) (PS-b-PEO, Mn, PS = 20,000 g / mol, Mn, PEO = 6,500 g / mol) in 1,4-dioxane (1,4-dioxane) Dissolved in% to prepare a reverse micelle solution.

Step 2: preparing a titanium dioxide sol-gel precursor solution

To 5 ml of isopropanol containing 0.71 g of titanium tetra-isopropoxide (Aldrich), 0.25 g of concentrated hydrochloric acid (37%) was added and stirred for 2 hours to prepare a titanium dioxide sol-gel precursor solution. Prepared.

Step 3: preparing a titanium dioxide-diblock copolymer thin film

The reverse micelle solution prepared in step 1 and the titanium dioxide sol-gel precursor solution prepared in step 2 were mixed at 40% by volume, stirred for 24 hours, dropped onto a silicon substrate, and spin-coated at 2500 rpm for 60 seconds. Titanium dioxide-diblock copolymer thin films were prepared.

Step 4: preparing a carbon-titanium dioxide nanostructure thin film

The thin film prepared in step 3 was put into a vacuum container and irradiated with ultraviolet rays of 254 nm wavelength at 25 W / cm 2 for 1 hour to allow polystyrene blocks of the biblock copolymer to crosslink and cure. After completing the above process, the thin film was put into an electric furnace and heated at 600 ° C. for 1 hour in an argon (Ar) atmosphere to change the polystyrene block into a carbon component, thereby forming a hybrid carbon-titanium dioxide nanostructure in which carbon nano dots are arranged in a titanium dioxide base A thin film was prepared.

< Example  2> hybrid  Preparation of Carbon-Titanium Dioxide Nanostructure Thin Films 2

The same method as in Example 1 was carried out, except that toluene was used as the solvent of step 1, and the titanium dioxide sol-gel precursor solution of step 3 was mixed at 10% by volume. An arrayed hybrid carbon-titanium dioxide nanostructure thin film was prepared.

< Example  3> hybrid  Preparation of silver-titanium dioxide nanostructure thin film 1

The titanium dioxide sol-gel precursor solution of step 3 was mixed at 50% by volume, and the silver nitrate solution prepared by dissolving silver nitrate (Aldrich) salt in isopropanol at a concentration of 1.0% by weight of ethylene oxide in a reverse micelle solution. Was mixed at 0.5 molar ratio (Ag / EO), and irradiated with ultraviolet rays of the same 254 nm wavelength as that used in Step 4 for 5 hours at 25 W / cm &lt; 2 &gt; A hybrid silver-titanium dioxide nanostructure thin film was prepared in the same manner as in Example 1 except that the polystyrene block and the polyethylene oxide block of the diblock copolymer were removed.

< Example  4> hybrid  Preparation of Silver-Titanium Dioxide Nanostructure Thin Films 2

The titanium dioxide sol-gel precursor solution of step 3 was mixed at 50% by volume, and the silver nitrate solution prepared by dissolving silver nitrate (Aldrich) salt in isopropanol at a concentration of 1.0% by weight of ethylene oxide in a reverse micelle solution. Was mixed at 0.7 molar ratio (Ag / EO), and irradiated with ultraviolet rays of the same 254 nm wavelength as that used in Step 4 for 5 hours at 25 W / cm 2 energy intensity instead of performing the curing and carbonization process performed in Step 4. A hybrid silver-titanium dioxide nanostructure thin film was prepared in the same manner as in Example 1, except that the polystyrene block and the polyethylene oxide block of the diblock copolymer were removed.

< Experimental Example  1> hybrid  Surface Morphology Analysis of Carbon-Titanium Dioxide Nanostructure Thin Films

The hybrid carbon produced by the method according to the invention to determine the surface form of the titanium dioxide nano-structure thin film analysis by atomic force microscopy (AFM, Digital Instruments, USA) and the results are shown in Figure 2.

FIG. 2 is a height-contrast photograph of a surface of a thin film having a different structure depending on the content of a titanium dioxide sol-gel precursor solution. FIG. FIG. 2 (A) shows a thin film (step 3 of Example 2) prepared by using toluene as a solvent for dissolving an amphiphilic diblock copolymer and containing 10% by volume of a titanium dioxide sol-gel precursor solution. In the photograph, it can be seen that the bright yellow circular dots are titanium dioxide-polyethylene oxide nanodots arranged in a polystyrene matrix and consist of a hexagonal arrangement of uniform size. 2B is a thin film prepared by using 1,4-dioxane as a solvent for dissolving an amphiphilic diblock copolymer and containing 40% by volume of a titanium dioxide sol-gel precursor solution (step of Example 1) 3) shows a hexagonal dense nanodot array similarly to (A) of FIG. 2, and it can be seen that the bright yellow polystyrene nanodots are uniformly arranged in the titanium dioxide-polyethylene oxide base. 2 (C) is a photograph showing a nanostructure thin film irradiated with ultraviolet rays and heat-treated to the thin film prepared in step 3 of Example 2, the hexagonal dense similar to Figure 2 (A) after ultraviolet irradiation and heat treatment It can be seen that the arrangement is maintained and the light yellow titanium dioxide nano dots are arranged on the dark brown carbon base. FIG. 2 (D) is a photograph showing a nanostructure thin film irradiated with UV and heat-treated to the thin film prepared in Step 3 of Example 1, and the surface having a shape opposite to that of FIG. 2B after UV irradiation and heat treatment. 2B shows light yellow polystyrene nanospots as dark brown carbon nanodots, and the titanium dioxide-polyethylene oxide base is changed to titanium dioxide base to have a hexagonal arrangement of carbon nanopoints on the titanium dioxide base. It can be seen that the structure is formed.

< Experimental Example  2> hybrid  Of carbon-titanium dioxide nanostructure thin film Raman analysis

The hybrid carbon-titanium dioxide nanostructure thin film prepared by the method according to the present invention was analyzed by Raman spectroscopy (MePherson 207 spectrometer, USA), and the results are shown in FIG. 3 .

A DPSS laser has a range of 488 10 ^-6 ㎡ ㎚ intensity of the wavelength and 30 mW in the hybrid nanostructure thin film prepared by the process according to the invention were investigated, it performs this analysis by micro-Raman.

In general, the material containing carbon is gatneunde two characteristic peaks, 1300-G is a band at 1600 ㎝ ^-1-band and D 1500 at 1400 ㎝ ^-1. D and G bands appeared in both the thin film containing 10% by volume of the titanium dioxide sol-gel precursor (step 3 of Example 2) and the thin film containing 40% by volume (step 3 of Example 1), which was green. It is indicated by an arrow. The vast peak seen in the 1400-1500 cm ^-1 range comes from the polystyrene-block-polyethylene oxide, a biblock copolymer before carbonization, and is distinct from the D and G bands. It can be seen that the G band near 1560 cm ⁻¹ appears relatively larger in both the step 3 thin film of Example 2 and the step 3 thin film of Example 1, which is a nanocrystalline carbon produced by carbonization of the polystyrene block. And sp ² -based on mixed carbon atoms. From this, it can be confirmed that the carbonization of the polystyrene block was successfully carried out by performing the heat treatment process of direct carbonization.

< Experimental Example  3> hybrid  Internal Structure Analysis of Carbon-Titanium Dioxide Nanostructure Thin Films

In order to determine the internal structure of the hybrid nanostructure thin film manufactured by the manufacturing method according to the present invention, a high resolution transmission electron microscope (HRTEM, JEOL, Japan) and an energy dispersive X-ray spectrometer (EDX, JEOL, Japan) were analyzed. the results are shown in Fig.

In order to use a high resolution transmission electron microscope, a hybrid nanostructure thin film deposited on a silicon substrate was coated with carbon, and polyacrylic acid (PAA) was added dropwise, dried, detached, suspended in distilled water, and then polyacrylic acid. Specimens were prepared by dissolving in water and then extracting the rest with a copper grid.

4 (A) shows the hybrid nanostructure thin film prepared in Example 2, the black dots of the scattered appearance represents titanium dioxide nano-dots. The hollow hollow traces are the damaged parts of the specimen fabrication for transmission electron microscopy, and are expected to be where the titanium dioxide nanospots were originally located. The photograph inserted into (A) of FIG. 4 is an enlarged photograph of one of the titanium dioxide nanodots, and shows a grid pattern of about 0.176 nm intervals. 4B is a result of analyzing the components of the thin film prepared in Example 2 using an energy dispersive X-ray spectrometer, carbon (C) derived from the carbon-titanium dioxide component constituting the thin film, Titanium (Ti), oxygen (O) peaks and copper (Cu), which is a component of the grid used to prepare specimens of transmission electron microscopy, were detected. 4 (C) shows the hybrid nanostructure thin film prepared in Example 1, the dark part represents titanium dioxide matrix, and the uniformly arranged bright part represents carbon nanodots. FIG. 4C is an enlarged photograph of a portion of FIG. 4C, and it is found that titanium dioxide nanoparticles having a lattice pattern at about 0.169 nm intervals are concentrated around a carbon nanopoint. Can be. The distinct lattice pattern of the particles means high crystallinity, and it can be easily predicted that the crystallinity of the titanium dioxide particles is high. Figure 4 (D) is a result of analyzing the components of the thin film prepared in Example 1 using an energy dispersive X-ray spectrometer, carbon (C), titanium (Ti), Oxygen (O) peaks and copper (Cu), which is a component of the grid used in the preparation of specimens of transmission electron microscopy, were detected. The thin film prepared in Example 1 contained 40% by volume of titanium dioxide sol-gel precursor, so that the titanium dioxide sol-gel precursor content was higher than that of the thin film prepared in Example 2 (10% by volume of titanium dioxide sol-gel precursor). It can be seen that there are more titanium peaks.

< Experimental Example  4> hybrid  Surface morphology and internal structure analysis of silver-titanium dioxide nanostructure thin film

Atomic force microscopy (AFM, Digital Instruments, USA), high resolution transmission electron microscope (HRTEM, JEOL, Japan) to investigate the surface morphology and internal structure of the hybrid silver-titanium dioxide nanostructure thin film prepared by the method according to the present invention And an energy dispersive X-ray spectrometer (EDX, JEOL, Japan), and the results are shown in FIG. 5 .

FIG. 5A is a height-contrast photograph of the surface shape of the thin film prepared in Step 3 of Example 3, which is not subjected to UV irradiation, and has a hexagonal dense array of uniform size. Dots were clearly observed. 5B is a height-contrast photograph of the surface morphology of the hybrid nanostructure thin film prepared in Example 3 above. As all of the diblock copolymers surrounding the silver / titanium dioxide component are removed, it can be seen that a structure in which nanometer-sized holes are uniformly arranged is shown. 5 (C) is a photograph taken by a high-resolution transmission electron microscope of the thin film that has not undergone the ultraviolet irradiation process, which is an enlarged silver nanoparticles scattered in the titanium dioxide matrix, the silver nanoparticles appear black in the center of the figure. It can be seen that it has a grid pattern. FIG. 5D is a result of analyzing a thin film prepared in Step 3 of Example 3, which is not subjected to an ultraviolet irradiation process, using an energy dispersive X-ray spectrometer. A silver component derived from silver nanoparticles and a titanium component derived from titanium dioxide structure were detected, indicating that the silver nitrate solution was reduced to silver nanoparticles and the titanium dioxide sol-gel precursor solution was converted to titanium dioxide. Able to know. From this, it can be seen that adding an appropriate amount of silver does not affect the nanostructure of mesoporous titanium dioxide. Thus, one can expect both advantages to be achieved without competing in structure and property.

< Experimental Example  5> hybrid  Nanostructured thin film Photocatalyst  Activity analysis

In order to determine the degree of photocatalytic activity by ultraviolet light and visible light of the hybrid nanostructure thin film according to the present invention, the following experiment was performed.

An ultraviolet cuvette containing 5 ppm methylene blue was immersed in the thin films of Examples 1 and 2 to irradiate ultraviolet rays at a wavelength of 254 nm for a predetermined time, and the absorption peak near 664 nm. The intensity ratio (I / I ₀ ) was analyzed to measure photocatalytic activity, and the results are shown in FIG. 6 .

6 (A) is a graph showing the results of the photocatalytic activity of the silicon substrate, Figure 6 (B) is a thin film prepared in step 3 of Example 2 (contains 10% by volume of titanium dioxide sol-gel precursor) Figure 6 is a graph showing the photocatalytic activity test results, Figure 6 (C) is a graph showing the photocatalytic activity test results of the thin film prepared in step 3 of Example 1 (containing 40 vol% titanium dioxide sol-gel precursor). . The results of FIGS. 6A, 6B, and 6C show the relative absorbance decrease with respect to the absorbance of the initial methylene blue solution that changes over time as a percentage. The thin film prepared in step 3 of Example 2 and the thin film prepared in step 3 of Example 1 exhibit the same photocatalytic activity as that of the silicon substrate, and if the carbonization heat treatment process is not performed directly therefrom, It can be seen that it is not shown. FIG. 6E is a graph showing the photocatalytic activity test results of a silicon substrate not coated with any thin film as in FIG. 6A, and FIG. 6F is a hybrid nanoparticle prepared in Example 2 Figure 6 is a graph showing the photocatalytic activity test results of the structure thin film, Figure 6 (G) is a graph showing the photocatalytic activity test results of the hybrid nanostructure thin film prepared in Example 1. The result of FIG. 6 (E), (F) and (G) is expressed as a percentage and is represented by (H) of FIG. 6, (F) of FIG. 6 is 50%, and also (G) of FIG. ) Indicates that the relative absorbance of the methylene blue solution was reduced by 65%. From this, the thin films subjected to the direct carbonization heat treatment process showed a markedly improved photocatalytic activity than before the carbonization, the structure of the structure in which the carbon nano dots are arranged on the titanium dioxide nanostructure, the hybrid nanostructure thin film prepared in Example 1 It can be seen that the photocatalytic activity is superior to that of the structure (10 vol% sol-gel precursor) in which the structure (40 vol% sol-gel precursor) is the structure opposite to that of titanium dioxide nanostructures arranged on the carbon matrix. This is because electrons and holes generated by the charge transfer from the methylene blue in the excited state toward the catalyst or by irradiation with ultraviolet light promote the production of active materials such as radicals.

In addition, as shown in FIG . 7 , in the hybrid nanostructure thin films prepared in Examples 3 and 4, by adding silver, methylene blue showed a greater reduction rate than when using a thin film containing pure titanium dioxide. When the thin film of Example 3 (thin film containing silver particles in 0.5 molar ratio (Ag / EO) to ethylene oxide of reverse micelle solution) was about 10%, the thin film of Example 4 (reverse It can be seen that the photocatalytic activity was further increased by about 26% when the silver particles were contained in a 0.7 molar ratio (Ag / EO) relative to the ethylene oxide of the micelle solution. This is because the photoelectron migrates from titanium dioxide to silver particles and interferes with the recombination between the photoelectron-hole pairs. Holes are required to recombine with electrons, and the concentration of holes is so low that they are more likely to combine with reducing reactions that form active materials such as superoxide anion radicals. Radicals such as superoxide anion radicals are very strong oxidizing materials and can decompose organic materials very efficiently.

Further, the thin film of Example 1 and Example 2 was immersed in an ultraviolet cuvette containing 10 ppm para-nitrophenol (p-nitrophenol) to irradiate visible light corresponding to the range of 420 nm wavelength or more for a predetermined time, Photocatalytic activity was measured by analyzing the intensity ratio (C / C0) of the absorbance peak near 317 nm, and the results are shown in FIG. 8 .

8 (A) is a graph showing the results of the photocatalytic activity of the thin film prepared in Example 2, Figure 8 (B) is a graph showing the results of the photocatalytic activity of the thin film prepared in Example 1. The results of (A) and (B) of FIG. 8 are expressed as percentages by summating the relative absorbance decrease with respect to the absorbance of the initial para-nitrophenol solution that changes over time. FIG. 8A shows that the relative absorbance of the para-nitrophenol solution is reduced by 52% and FIG. 8B by 62%. FIG. 8D is a result obtained by calculating the average slope value by expressing the result of FIG. 8C in a natural log form. The larger the slope, the higher the photocatalytic activity, which is different from that of the control group having a value close to zero. Example 1 corresponds to a slope corresponding to 7.03 × 10 ⁻³ and Example 2 corresponds to 6.16 × 10 ⁻³ . Has a value. From this, it can be seen that the hybrid nanostructures prepared in Examples 1 and 2 exhibit a markedly enhanced photocatalytic activity in an environment in which not only ultraviolet rays but also visible rays are irradiated. In addition, in the case of Example 1 (structure in which carbon nano dots are arranged on a titanium dioxide nanostructure), as in the above result of evaluating activity by irradiating ultraviolet rays, Example 2 (carbon matrix) having a structure opposite thereto It shows that the photocatalytic activity is superior to that of the titanium dioxide nanopoints). In the case of evaluating photocatalytic activity through visible light irradiation, the nanostructure exhibits increased activity as a photocatalyst due to the generation of electron-hole pairs and the resulting radical promotion, as in the case of ultraviolet irradiation.

Claims (23)

Ultraviolet and visible photocatalysts comprising hybrid carbon-titanium dioxide nanostructure thin films.
The ultraviolet and visible photocatalyst of claim 1, wherein the hybrid carbon-titanium dioxide nanostructure is formed by arranging carbon nanopoints in a titanium dioxide matrix, or by arranging titanium dioxide nanopoints in a carbon matrix.
delete The method of claim 1, wherein the hybrid carbon-titanium dioxide nanostructures are manufactured according to the shape and arrangement of the structure according to the mixing ratio of the reverse micelle solution in which the amphiphilic diblock copolymer is dissolved and the titanium dioxide sol-gel precursor solution Ultraviolet and visible photocatalyst, characterized in that.
The hybrid carbon-titanium dioxide nanostructure thin film formed by arranging carbon nanodots in a titanium dioxide matrix is a titanium dioxide sol with respect to a reverse micelle solution in which an amphiphilic diblock copolymer is dissolved in 1,4-dioxane. -UV and visible photocatalyst, characterized in that the gel precursor solution is mixed by 38-50% by weight, spin-coated to the substrate, and then irradiated with ultraviolet rays and heat treated.
3. The hybrid carbon-titanium dioxide nanostructure thin film formed by arranging titanium dioxide nanopoints in a carbon matrix is a titanium dioxide sol-gel precursor solution for a reverse micelle solution in which an amphiphilic diblock copolymer is dissolved in toluene. Ultraviolet and visible photocatalyst, characterized in that the mixture is prepared by spin-coating to a substrate by mixing in an amount of 8 to 12% by weight and irradiated with ultraviolet rays and heat treatment.
delete delete Dissolving the amphiphilic diblock copolymer in a solvent to prepare a reverse micelle solution (step 1);
Dissolving the titanium dioxide precursor in a solvent to prepare a titanium dioxide sol-gel precursor solution (step 2);
Mixing the reverse micelle solution prepared in step 1 with the sol-gel precursor solution prepared in step 2 and spin-coating the substrate to prepare a titanium dioxide-diblock copolymer thin film (step 3); And
The method of manufacturing the hybrid carbon-titanium dioxide nanostructure thin film of claim 1, comprising the step (4) of carbonizing or removing the diblock copolymer by irradiating ultraviolet rays to the thin film prepared in step 3 and then heat treating the thin film.
10. The method of claim 9, wherein the amphiphilic diblock copolymer of step 1 is poly (styrene-block-ethylene oxide).
10. The method of claim 9, wherein the solvent of step 1 is 1,4-dioxane or toluene.
10. The method of claim 9, wherein the reverse micelle solution of step 1 contains 0.1-1 wt% of an amphiphilic diblock copolymer.
The hybrid carbon dioxide of claim 9, wherein the titanium dioxide precursor of step 2 is titanium tetra-isopropoxide, titanium tetrabutoxide, or titanium alkoxide. Method for producing a titanium dioxide nanostructure thin film.
The method of claim 9, wherein the solvent of step 2 is ethanol or isopropanol.
10. The hybrid carbon-titanium dioxide of claim 9, wherein the mixing of step 3 comprises mixing the titanium dioxide sol-gel precursor solution in an amount of 8-12 wt% with respect to the reverse micelle solution when forming the titanium dioxide nanodots. Method of manufacturing nanostructured thin film.
The hybrid carbon-titanium dioxide of claim 9, wherein the mixing of step 3 comprises mixing the titanium dioxide sol-gel precursor solution with 38-50 wt% of the reverse micelle solution when forming the carbon nanodots. Method of manufacturing nanostructured thin film.
The method of manufacturing a hybrid carbon-titanium dioxide nanostructure thin film according to claim 9, wherein the spin coating of step 3 is performed at a speed of 2000-3000 rpm.
10. The method of claim 9, wherein the ultraviolet irradiation in Step 4 is performed for 50 to 70 minutes at 20 to 30 W / cm &lt; 2 &gt; energy intensity with ultraviolet rays of 254 nm wavelength for the hybrid carbon-titanium dioxide nanostructure thin film. .
The method of claim 9, wherein the heat treatment of Step 4 is performed at 550-650 ° C. for 50-70 minutes in an argon atmosphere. delete delete delete delete

Images