JP2006104541A - Method for forming thin film of amorphous titanium oxide, and photocatalytic composite thin film - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for forming a thin film of amorphous titanium oxide having excellent photocatalytic performance. <P>SOLUTION: The method for forming the thin film of amorphous titanium oxide having the photocatalytic performance includes forming the titanium oxide film on a substrate, while irradiating the substrate or a vapor flow of evaporated titanium oxide, with an ion beam. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a method for forming an amorphous titanium oxide thin film having a photocatalytic function. The present invention also relates to a photocatalytic composite thin film provided with an amorphous titanium oxide thin film having a photocatalytic function and a hydrophilic photocatalytic composite thin film having antifogging property or self-cleaning property.

  Conventionally, anatase-type titanium oxide has attracted attention as a photocatalyst, and when this is irradiated with ultraviolet rays having a wavelength shorter than 380 nm, it causes an oxidation-reduction reaction such as a water decomposition reaction. Known as “effect”. Based on this effect, various application products in which a titanium oxide film or a thin film is provided on the surface of the substrate have been tried, and some of them have been put into practical use. Such a thin film of titanium oxide having a photocatalytic function can be formed under certain conditions by a physical vapor deposition method (PVD method), a chemical vapor deposition method (CVD method), a sol-gel method using an alkoxy body, or the like. it can.

  For example, as a titanium oxide photocatalyst film forming method at room temperature, an example in which a film is formed on a polycarbonate substrate by reactive sputtering has been reported (for example, see Non-Patent Document 1). However, since the sputtering method has an extremely slow film formation rate, it has not reached a practical production standpoint. Further, a gas flow sputtering method has been announced as a method of increasing the film forming speed (see, for example, Non-Patent Document 2). However, the film forming temperature and the film forming speed are unclear and are not practical yet.

  As a practical example, there is a film forming method in which alkoxy titanium is hydrolyzed (see, for example, Patent Document 1). However, since the curing temperature of alkoxy titanium is high, it cannot be formed on a general-purpose plastic substrate. In addition, a vacuum deposition method can be mentioned, but in order to obtain anatase-type titanium oxide, the substrate heating temperature needs to be 200 ° C. or higher (see, for example, Patent Documents 2 to 4). Can not be membrane.

In order to form a titanium oxide film on a general-purpose plastic substrate, it is necessary to lower the substrate heating temperature. However, when the substrate heating temperature is lowered, the structure of the titanium oxide film is generally not anatase type titanium oxide but amorphous. A titanium oxide film is formed. Amorphous titanium oxide has been said to have insufficient charge separation and a significant decrease in photocatalytic activity.
ULVAC TECHNICICAL JOURNAL No, 56 P6-9 (2002) 50th Applied Physics Related Conference, Proceedings, 28p-F-16 (2003) JP-A-8-108075 JP 10-36144 A JP-A-10-330131 JP 2000-53449 A

  An object of this invention is to provide the formation method of the amorphous titanium oxide thin film which has the outstanding photocatalytic performance. Another object of the present invention is to provide a photocatalytic composite thin film that exhibits photocatalytic performance including an amorphous titanium oxide layer having photocatalytic performance.

  Another object of the present invention is to provide a hydrophilic photocatalyst composite thin film having antifogging or self-cleaning properties, further comprising a silicon oxide layer on the titanium oxide layer of the photocatalytic composite thin film.

  As a result of repeated investigations on a titanium oxide film forming method, the present inventors have made a so-called IAD method (Ion-beam Assisted Deposition, an ion assisted vapor deposition method) in which film formation is performed while irradiating a substrate or titanium oxide vapor with ions during vacuum vapor deposition. ) Was found to achieve the above-mentioned problems, and the present invention was made based on this finding.

  That is, the present invention provides a method for forming an amorphous titanium oxide thin film having photocatalytic performance on a low-temperature substrate while irradiating an ion beam to a vapor stream of titanium oxide on the substrate or during vapor deposition. The ion beam preferably has an applied voltage at irradiation of 300 V or more and an irradiation output of 300 W or less, and the substrate heating temperature is preferably 150 ° C. or less.

  The present invention also includes a substrate, a base layer made of metal, metal oxide or a mixture thereof provided on the substrate, and an amorphous titanium oxide layer having a photocatalytic function provided on the base layer. The photocatalytic composite thin film is provided, wherein the titanium oxide layer is formed while irradiating an ion beam on a vapor stream of titanium oxide on a substrate.

  Furthermore, the present invention provides a hydrophilic photocatalytic composite thin film having an antifogging property or self-cleaning property provided with a silicon oxide layer on the titanium oxide layer of the photocatalytic composite thin film. The thickness of the silicon oxide layer is preferably 5 to 30 nm.

  According to the present invention, a photocatalytic titanium oxide thin film having a photocatalytic performance equivalent to a photocatalytic titanium oxide thin film containing anatase type crystals obtained at a substrate heating temperature of 300 ° C. or higher can be produced at a substrate heating temperature of 150 ° C. or lower. It becomes possible.

  In addition, according to the present invention, it is possible to impart a photocatalytic function to the surface of plastic, paper, fiber, cloth, and the like, which are low heat resistant materials that could not be thermally formed conventionally.

  Furthermore, according to the present invention, since the ion-assisted deposition method is used, the film formation rate is faster than the reactive sputtering method used for the conventional low-temperature titanium oxide photocatalyst film formation, thereby reducing the manufacturing time. It becomes possible to plan.

(Titanium oxide thin film)
The amorphous titanium oxide thin film having photocatalytic performance of the present invention is characterized in that a titanium oxide film is formed on a substrate while irradiating an ion beam to a vapor stream of titanium oxide on the substrate or during vapor deposition. Can be formed.

In this specification, “amorphous titanium oxide” means that a peak peculiar to anatase type titanium oxide does not appear by X-ray diffraction (XRD) measurement, and a peak peculiar to anatase type titanium oxide appears by Raman spectroscopic measurement. Means no. In the case of anatase type titanium oxide, specific peak, appears in 2 [Theta] = 25.3 ° in X-ray diffraction, the Raman spectrophotometry main peak 147cm ^-1, but appears to the sub-peak 640,398,515Cm ^-1, Amorphous titanium oxide does not show these peaks.

  As a method for forming a thin film of amorphous titanium oxide, for example, a film forming method by a PVD method such as vacuum deposition with ion or plasma assist and ion plating may be used. An example of a conceptual diagram of a vapor deposition apparatus used for such a film forming method is shown in FIG.

  In FIG. 1, a vacuum chamber 1 includes an electron gun 2, a hearth 3 on which titanium oxide as a deposition material is set, an ion gun 5, a substrate 7 set on a jig 8, and a substrate heating heater 9. The ion gun 5 is arranged so that the ion beam 6 can irradiate the vapor stream 4 and the substrate 7. The jig 8 has a rotating structure. A shutter 10 is disposed on the hearth 3 and is opened at the start of vapor deposition.

  Next, an example of a process for forming an amorphous titanium oxide thin film having photocatalytic performance will be described in the following (1) to (5) with reference to FIG.

(1) The inside of the vacuum chamber 1 is evacuated to 3 × 10 ⁻⁵ Torr or less. At the same time, the substrate 7 is heated at 150 ° C. or lower by the substrate heating heater 9 as necessary. Although the material of the substrate 7 is not limited, for example, low heat resistant plastics such as glass, ceramic, polycarbonate, polyester, acrylic, nylon, ABS, and the like having a heat resistant temperature of 150 ° C. or less, paper, and fibers can be used.

  (2) Argon gas is introduced into the ion gun 5 and the ion gun is turned on to irradiate the substrate 7 with the ion beam 6.

  (3) Oxygen gas is introduced into the vacuum chamber 1 to an arbitrary pressure.

  (4) Titanium oxide of Hearth 3 is heated by the electron gun 2 and the shutter 10 is opened to start vapor deposition.

  (5) When the desired film thickness is reached, the shutter 10 is closed and vapor deposition is terminated.

  Amorphous titanium oxide thin film formed by PVD at a substrate temperature of 150 ° C. or lower is also found to exhibit a certain degree of photocatalytic properties, and vapor deposition is a method for forming an amorphous titanium oxide thin film having a form that facilitates charge separation. The titanium oxide vapor flow is irradiated with an ion beam, and the ions collide with the titanium oxide particles in the vapor flow (including the titanium oxide particles that have reached the substrate surface). A film was formed. Although this thin film is amorphous, it is thought that valence band electrons are excited when irradiated with ultraviolet rays, and the structure becomes more easily separated.

  Accordingly, it is preferable to set the applied voltage at the time of beam irradiation of the ion gun to 300 V or more and the irradiation output to 300 W or less so that the energy of individual ions to be used is increased. According to this output, the ion beam collides with the titanium oxide particles in the vapor stream (including the titanium oxide particles that have reached the substrate surface), and the surface of the titanium oxide particles is activated. It is considered that a titanium oxide thin film that is easily separated and has a good photocatalytic action is formed on the substrate surface.

(Photocatalytic composite thin film)
In the present invention, a photocatalytic composite thin film may be formed by providing a base layer made of a metal, a metal oxide, or a mixture thereof on a substrate and providing the titanium oxide layer thereon. An example of a hydrophilic photocatalytic composite thin film may be formed by further forming a silicon oxide layer on the titanium oxide layer of the photocatalytic composite thin film to provide a hydrophilic photocatalytic composite thin film having antifogging property or self-cleaning property. Is shown in the cross-sectional view of FIG.

  In the photocatalytic composite thin film of FIG. 2, a base layer 21 is formed on a substrate 20, a titanium oxide layer 22 is formed thereon, and a silicon oxide layer 23 is formed thereon.

  The material of the substrate 20 is not particularly limited. For example, low heat resistant plastics such as ceramic, polycarbonate, polyester, acrylic, nylon, and ABS, heat resistant temperature of 150 ° C. or less, paper, fiber, glass, and the like may be used. .

  The base layer 21 is a layer that contributes to preventing damage to the substrate 20 due to photoexcitation of the titanium oxide layer 22 (photocatalyst) and preventing film peeling caused by thermal effects (expansion and contraction). As the base layer, for example, a metal such as chromium, aluminum, titanium or stainless steel or an alloy thereof, a metal oxide such as silicon, aluminum, tantalum, tin, cerium or indium tin, or calcium, magnesium or aluminum Metal fluorides can be used. When the substrate 20 is made of transparent plastic (polycarbonate), it is preferable to use transparent tin oxide for the base layer from the viewpoint of improving adhesion. The thickness of the base layer is not particularly limited. As the base layer, the above substances may be stacked on the substrate as a single layer, or two or more layers may be stacked. When two or more layers are laminated, light shielding, anti-glare utilizing refraction, colorization (including a filter), and the like can be achieved. Further, when combined with a conductive material, it can be used as a heating element, realizing multi-function. The base layer may be omitted if the substrate is a material that is not damaged by photocatalysis.

The titanium oxide layer (TiO ₂ ) 22 is amorphous but exhibits a photocatalytic effect. The film thickness is not particularly defined, but is preferably 100 nm or more, more preferably about 150 to 1000 nm in consideration of the catalyst performance in the evaluation of oil decomposability.

Although the silicon oxide layer (SiO ₂ ) 23 does not have a photocatalytic function, the surface thereof is covered with Si—OH groups having an affinity for water, and therefore the silicon oxide layer 23 is provided on the titanium oxide layer 22. , The hydrophilic performance is further enhanced. It also contributes to improving the durability of the film surface (wear, contamination, chemical properties, etc.). In order to maintain practical hydrophilic performance and self-cleaning properties, the film thickness should be not too thick, preferably about 5 to 30 nm, and more preferably 5 to 20 nm.

  Next, a method for forming a hydrophilic photocatalytic composite thin film will be described with reference to (6) to (8). In particular, when the silicon oxide layer is not formed, the photocatalytic composite thin film can be formed from the steps (6) and (7).

  (6) The base layer 21 is formed by vapor deposition in an atmosphere in which the surface of the substrate 20 is irradiated with the ion beam 6 (so-called ion-assisted vapor deposition).

  (7) A titanium oxide layer 22 (photocatalyst) is formed on the surface of the base layer 21 by vapor deposition in an atmosphere irradiated with the ion beam 6 (so-called ion-assisted vapor deposition).

  (8) A silicon oxide layer 23 is formed on the surface of the titanium oxide layer 22 by vapor deposition. The vapor deposition may be performed in an atmosphere irradiated with an ion beam (so-called ion-assisted vapor deposition). In the case of ion-assisted deposition, silicon oxide is densely deposited and a hard silicon oxide layer can be obtained, so that ion-assisted deposition can be performed according to the desired hardness of the silicon oxide layer.

    The effect of the ion beam 6 used at the time of film formation is considered to be an effect of cleaning and activating the surface of the substrate 20 and thermally activating the evaporated deposition material. In particular, when the titanium oxide layer 22 is formed, it is preferable to set the applied voltage of the ion gun 5 as high as 300 V or more and the output as high as 300 W (current: 0.03 to 1 A) or less. With this setting, it is considered that each ion irradiated from the ion beam 6 has a large energy. The ions collide with titanium oxide particles in the vapor stream 4 (including titanium oxide particles that have reached the substrate surface), whereby titanium oxide particles are formed in a high energy state. This film is considered to have a structure in which valence band electrons are excited when irradiated with ultraviolet rays, and charge separation is easier. Therefore, it is considered that a titanium oxide thin film having a good photocatalytic action is formed on the substrate surface even when the substrate is at a low temperature. For the formation of a film having a photocatalytic function, it is preferable to form the film with a beam irradiation output of the ion gun 5 of 300 W or less. By maintaining the plastic substrate 20 at a negative potential, the kinetic energy of the titanium oxide particles is taken into consideration, and it is considered that an effective titanium oxide photocatalyst is obtained.

  In addition, the base layer 21 of said (6) can be produced according to the procedure of (6a)-(6g) below.

(6a) The inside of the vacuum chamber 1 is evacuated to 3 × 10 ⁻⁵ Torr or less.

(6b) The substrate 7 (corresponding to 20 in FIG. 2) is heated by the substrate heating heater 9 as necessary.
(6c) Argon gas is introduced into the ion gun 5, the ion gun is turned on, and the substrate 7 is irradiated with the ion beam 6.

  For the purpose of improving the cleaning property of the substrate surface, the applied voltage at the time of beam irradiation of the ion gun was set to 4 to 500 V, and the irradiation output was irradiated for 5 minutes at 300 W or less (current 0.5 to 0.75 A).

(6d) Oxygen gas is introduced into the vacuum chamber 1 to an arbitrary pressure.

(6e) Irradiation with an ion beam under the same conditions during vapor deposition for the purpose of increasing the density of the base layer film.

(6f) The evaporation material of the hearth 3 is heated by the electron gun 2 and the shutter 10 is opened to start the evaporation.

(6g) When the desired film thickness is reached, the shutter 10 is closed and the vapor deposition is finished. Thereafter, a titanium oxide film is formed.

  Moreover, the silicon oxide layer 23 of the above (8) can be prepared according to the following (8a) to (8b).

(8a) After the titanium oxide film is formed, the evaporation material of the hearth 3 is heated by the electron gun 2 and the shutter 10 is opened to start the evaporation.

(8b) When the film thickness is arbitrary, the shutter 10 is closed and the vapor deposition is finished.

  The product to which the photocatalytic composite thin film of the present invention is applied is not particularly limited, but it is formed on spectacles, cameras, optical equipment lenses, mirrors, window glass, H / L lenses, reflectors, etc. to prevent fogging and water droplets Can do. Further, it can be formed on an outer wall material, a plastic signboard, a shoji paper, a fiber, a cloth, a fluorescent lamp device, and the like to prevent contamination. Furthermore, it can be formed on plastic interiors, exteriors, ornaments, sign plates, etc. to prevent contamination.

Example 1
The titanium oxide thin film of the present invention was prepared as follows.

(1) An electron gun 2, a hearth 3 in which a deposition material (titanium oxide) is set in the vacuum chamber 1, an ion gun 5, and a substrate 7 set in a jig 8 (samples prepared under the same conditions are used for later evaluation. Therefore, a glass substrate and a polycarbonate substrate were set simultaneously) and a substrate heating heater 9 was disposed.

(2) The ion gun 5 is arranged so that the ion beam 6 can irradiate the vapor flow 4 and the substrate 7. The ion gun was arranged so that the ion irradiation angle was about 30 ° with respect to the substrate. The power source of the ion gun 5 was Pinnacle ^™ 6 × 6 KW, and the ion gun was SCIS-12RMP-MAG (both made by Advanced Energy).

(3) The inside of the vacuum chamber 1 was evacuated to 3 × 10 ⁻⁵ Torr or less. At the same time, the substrate 7 was heated to 50 ° C. by the substrate heating heater 9.

(4) Argon gas was introduced into the ion gun 5 and the ion gun was turned on to irradiate the substrate 7 with the ion beam 6. The beam output of the ion gun 5 was set to 1500 V-0.1 A (power 150 W). In this state, the surface of the substrate was irradiated with ions for 2 minutes. At this time, the pressure in the vacuum chamber was 8 × 10 ⁻⁵ Torr.

(5) Next, oxygen gas was introduced into the vacuum chamber 1 until it reached 4 × 10 ⁻⁴ Torr.

(6) Titanium oxide of Hearth 3 was heated by the electron gun 2 and the shutter 10 was opened to start vapor deposition.

(7) The film thickness of the titanium oxide was monitored with a quartz film thickness meter. When the film thickness reached 250 nm, the shutter 10 was closed to complete the vapor deposition, and titanium oxide was deposited on the glass and polycarbonate substrate surfaces to prepare samples.

(Comparative Examples 1-4)
Samples were prepared in the same manner as in Example 1 except that the samples were prepared at substrate heating temperatures of 50 ° C, 150 ° C, 200 ° C, and 300 ° C without ion irradiation (except for step (4)). did.

(Test Example 1 X-ray diffraction measurement, Raman spectrum measurement and refractive index measurement)
A sample obtained by forming a titanium oxide thin film on a glass substrate in Example 1, Comparative Example 1, Comparative Example 3, and Comparative Example 4 was thinned using a thin film X-ray diffractometer (RINT2000 vertical goniometer, manufactured by Rigaku Corporation). X-ray diffraction measurement was performed. X-ray diffraction (XRD) measurement conditions are as follows.

X-ray source: Cu Kα
Applied voltage: 40 kV, applied current: 200 mA
Scanning mode: 2θ scan X-ray incident angle: θ = 1 °
Sample stage: Rotating sample stage (in-plane rotation; one-way rotation 72 rpm)
Incident slit: 0.4 mm
Incident height limiting slit: 5 mm
Width-limited light receiving slit: 8.0 mm
Diffraction X-ray monochromator: Graphite flat crystal (200)
Detector: Scintillation counter Scan speed: 4.000 ° / min
Scan step: 0.020 °
Scanning range: 5.000-80.000 °
The results of these X-ray diffractions are shown in FIG. According to FIG. 3, in the samples of Example 1, Comparative Example 1 and Comparative Example 3, the presence of peaks peculiar to anatase-type titanium oxide crystals was not observed. On the other hand, in the sample of Comparative Example 4, the presence of a peak from the (101) plane appearing at 2θ = 25.3 °, which is characteristic of anatase-type titanium oxide crystals, was confirmed.

  In addition, a sample obtained by forming a titanium oxide thin film on a glass substrate in Example 1, Comparative Example 1, Comparative Example 3 and Comparative Example 4, using a microscopic Raman spectroscopic analyzer (manufactured by Renishaw, UK, model: RAMASCOPE System 2000). Raman spectra were also measured. The measurement conditions of the Raman spectrum are as follows.

Excitation wavelength: 514.5 nm (argon laser)
Laser head power: 30mW
Objective lens magnification: 50x
Measurement area size: Sample surface about 2μmφ
Rayleigh light cut method: using holographic notch filter
Spectroscopic method: diffraction grating
Detector: Peltier-type air-cooled CCD detector (576 x 384 pixels)
Detector exposure time: 30 seconds, detector gain: High
Measurement wave number range: 100 to 800 cm ⁻¹
Usually, the spectral peak position of an anatase type crystal is a main peak 147 cm ⁻¹ , and appears in sub-peaks 640, 398, 515 cm ⁻¹ (in order of intensity). Although the peak intensity varies considerably depending on the optical axis adjustment, if the Si wafer is used as a standard sample if it is sufficiently adjusted, the maximum peak of Si (520 cm ⁻¹ ) is 10,000 cps or more under the above measurement conditions. Achieve strength. All the data is measured under this adjustment. Under this adjustment, it is possible to detect anatase crystal layer peak (147 cm ⁻¹ ) having a thickness of several nm.

The measurement results of these Raman spectra are shown in FIG. According to FIG. 4, in the samples of Example, Comparative Example 1 and Comparative Example 3, the presence of peaks peculiar to anatase-type titanium oxide crystals was not observed. On the other hand, in the sample of Comparative Example 4, the presence of peaks peculiar to the anatase-type titanium oxide crystal was confirmed at 145, 395, 517 and 636 cm ⁻¹ .

  Furthermore, when the refractive index of the sample of Example 1 and Comparative Examples 1-4 was measured using an ellipsometer (product name: SD2300, manufactured by Philips), the sample of Example 1 showed a refractive index n = 1.96. The sample of Comparative Example 1 had a refractive index n = 1.66, the sample of Comparative Example 2 had n = 1.73, and the sample of Comparative Example 3 had n = 1.90. In the sample of Comparative Example 4, n = 2.31.

(Test Example 2 Measurement of water droplet contact angle on the surface of the titanium oxide layer)
After applying 0.1 wt% engine oil-dichloromethane solution (engine oil; castle motor oil) as a contamination source to the surface of the sample formed by depositing titanium oxide on the glass substrate prepared in Example 1 and Comparative Examples 1-4, the surface A drop of pure water was dropped on the top, and the contact angle of the water drop was measured with a contact angle meter (CA-X, manufactured by Kyowa Interface Science Co., Ltd.) as an initial value. Thereafter, the sample was irradiated with ultraviolet rays (λ ₀ = 360 nm) of 0.95 to 1.2 mW / cm ² for 7 hours (ultraviolet measurement; ultraviolet dosimeter UVR-1, manufactured by Topcon Corporation) at the time of application of engine oil (initial value) ) To a water drop contact angle every 7 hours up to 7 hours later was measured with a contact angle meter. These results are shown in FIG.

  According to FIG. 5, the sample of Example 1 formed at a substrate temperature of 50 ° C. has a water droplet contact angle value as compared with the samples of Comparative Examples 1 to 3 formed at substrate temperatures of 50, 150, and 200 ° C., respectively. Of the photocatalyst hydrophilicity is exhibited, and the photocatalytic hydrophilicity is equivalent to that of the sample of Comparative Example 4 formed at a substrate temperature of 300 ° C.

(Test Example 3 Measurement of water droplet contact angle on the surface of the silicon oxide layer)
In order to improve the hydrophilicity and durability (mechanical and chemical) of the photocatalytic composite thin film, a sample was prepared by depositing titanium oxide on a glass substrate in the same manner as in Example 1, Comparative Example 1 and Comparative Example 2. Subsequently, 7 nm of silicon oxide was deposited on the surface of the titanium oxide layer continuously (without opening the vacuum chamber to the atmosphere).
For the silicon oxide layer, first, the hearth 3 is rotated, the silicon oxide material is set at the electron beam irradiation position, and then the silicon oxide of the hearth 3 is heated by the electron gun 2 and the shutter 10 is opened to start the deposition. The film thickness of the silicon oxide was monitored with a crystal film thickness meter, and when the thickness reached 7 nm, the shutter 10 was closed to complete the deposition, and the film was formed.

Then, in the same manner as in Test Example 2, after applying the contamination source to the surface of the silicon oxide layer of each sample, a drop of pure water was dropped on the surface, and the contact angle meter (CA-X, Kyowa Interface Science Co., Ltd.) The initial value was measured. Thereafter, the sample was irradiated with ultraviolet rays of 0.95 to 1.2 mW / cm ² for 7 hours (ultraviolet ray measurement; ultraviolet dosimeter UVR-1, manufactured by Topcon Corporation) every hour since engine oil application (initial value). The water droplet contact angle up to 7 hours later was measured with a contact angle meter. These results are shown in FIG. According to FIG. 6, since the water droplet contact angle is rapidly decreased in a short time in the sample of Example 1, it can be seen that the photocatalytic hydrophilization performance is remarkable with respect to the samples of Comparative Example 1 and Comparative Example 2.

(Test Example 4 Change in photocatalytic performance by changing the beam voltage)
Titanium oxide was applied to the glass substrate in the same manner as in Example 1 except that the beam current of the ion gun when forming the titanium oxide layer was 0.05 A and the beam voltages were changed to 300 V, 500 V, 1000 V, and 1500 V, respectively. Film-formed samples were prepared (Examples 2 to 5). After applying a contamination source to the surface of the titanium oxide layer of the prepared sample in the same manner as in Test Example 2, a drop of pure water was dropped on the surface, and the contact angle meter (CA-X, manufactured by Kyowa Interface Science Co., Ltd.) The initial value was measured. Thereafter, the sample was irradiated with ultraviolet rays of 0.95 to 1.2 mW / cm ² for 5 hours (ultraviolet measurement; ultraviolet dosimeter UVR-1, manufactured by Topcon Corporation), and each water droplet contact angle was measured with a contact angle meter. Measured. These results are shown in Table 1 and FIG.

  From these results, it was found that the photocatalytic performance of the sample was improved as the beam voltage of the ion gun when forming the titanium oxide layer was increased.

(Test Example 5 Change in photocatalytic performance by changing beam current)
The glass substrate was oxidized in the same manner as in Example 1 except that the beam voltage of the ion gun when forming the titanium oxide layer was 1500 V and the beam currents were changed to 0.03 A, 0.05 A, and 0.2 A, respectively. Samples in which titanium was formed were prepared (Examples 6 to 8). After applying a contamination source to the surface of the titanium oxide layer of the prepared sample in the same manner as in Test Example 2, a drop of pure water was dropped on the surface, and the contact angle meter (CA-X, manufactured by Kyowa Interface Science Co., Ltd.) The initial value was measured. Thereafter, the sample was irradiated with ultraviolet rays of 0.95 to 1.2 mW / cm ² for 5 hours (ultraviolet measurement; ultraviolet dosimeter UVR-1, manufactured by Topcon Corporation), and each water droplet contact angle was measured with a contact angle meter. Measured. These results are shown in Table 2 and FIG.

  These results show that the photocatalytic performance improves as the beam current increases, but the photocatalytic performance decreases when the current exceeds a certain level. However, it can be seen that the water droplet contact angle is remarkably lowered after 5 hours in any of the samples and has excellent photocatalytic performance. The sample of Example 1 has particularly excellent photocatalytic performance.

(Test Example 6 Measurement of radical amount of sample)
The sample of Example 1 irradiated with ions at the time of titanium oxide vapor deposition exhibited good photocatalytic performance as compared with the sample of Comparative Example 1 formed at the same substrate temperature (50 ° C.) but without ion irradiation ( (See FIG. 5). This phenomenon is because the sample formed by ion irradiation during deposition of titanium oxide has a structure in which valence band electrons are excited when irradiated with ultraviolet rays and charge separation is easier than in the sample formed without ion irradiation. It is considered to be a body. A spin trap agent (5,5-dimethyl-1-pyrroline-1-oxide (abbreviation: DMPO)) is dropped onto the sample surface by a spin trap ESR measurement method using an electron spin resonance analysis (ESR) apparatus. The amount of radicals generated from the surface of the thin film when irradiated with ultraviolet rays was measured and verified. If the sample is easily charge-separated, the amount of radicals generated under the influence of generated electrons and holes is considered to be large. The radicals generated are mainly hydroxy radicals (OH.), But react with the spin trap agent DMPO to form stable radicals (DMPO-OH.).

  The amount of stable radicals was measured by the following procedure.

  As a measurement sample, a sample obtained by forming a titanium oxide film on the glass substrate prepared in Example 1, Comparative Example 1 and Comparative Example 4, and a glass substrate were used.

(1) A cylinder (diameter: 1.5 cm) was set on each sample surface so that the DMPO aqueous solution did not leak.

(2) 200 μl of DMPO aqueous solution (DMPO: 5 μl, water: 195 μl) was dropped into the cylinder.

(3) The sample surface was irradiated with 1 mW / cm ² of ultraviolet light for 1 minute with a black light (center wavelength: 360 nm).

(4) After collecting the DMPO aqueous solution on the sample surface, 100 μl of this was put in the ESR aqueous solution sample cell.

(5) Set the ESR aqueous solution sample cell in the ESR apparatus and measure the amount of stable radicals. In addition, the time from the ultraviolet irradiation stop to the measurement start was 2 minutes.

  The radical measurement conditions are as follows.

Radical measurement method: Spin trap ESR measurement method ESR measurement conditions:
Central magnetic field: 335.6 mT ± 5 mT
・ Microwave: 9.416 GHz -8 mW
・ Modulation frequency: 100 KHz
・ Detector gain: 4 × 100
・ Time Constant: 0.1 sec
・ Measurement time: 4 min
ESR device: electron spin resonance analyzer (free radical detector) JER-FR80 (manufactured by JEOL Ltd.)
These results are shown in FIG. According to FIG. 9, since the spectrum of the sample of Example 1 has high A, B, C, and D peaks, it is shown that the amount of DMPO radicals is large. When the sample of Example 1 is compared with the sample of Comparative Example 1 in which the photocatalytic performance is inferior in Test Example 2, it is certainly suggested that the amount of DMPO radicals generated by ultraviolet irradiation is large and charge separation is easy. . In addition, Example 1 shows that the amount of DMPO-OH radicals is the same as that of the sample of Comparative Example 4 having an anatase crystal structure formed at a high temperature at 300 ° C. In addition, in the sample of the glass substrate (blank) which was not formed into a titanium oxide film, the spectrum peak was not seen, so DMPO-OH.radical was not detected (not shown).

(Test Example 7 Durability test by changing material of base layer)
The sample prepared in Example 1 in which a film of titanium oxide was formed on polycarbonate (PC), which was plastic, was irradiated with black light (1 ± 0.2 mW / cm ² ) ultraviolet rays for 7 days. Has become cloudy. This is because the PC on the contact surface between the titanium oxide thin film and the PC was eroded by the photocatalytic action. Therefore, a base layer is provided between the substrate layer and the titanium oxide layer in order to prevent erosion due to photocatalytic action. In order to select an appropriate base layer material, durability was evaluated by changing the base layer material.

As the base material, a metal material and a metal oxide material were used. As the metal material, chromium, titanium, and stainless steel (material 310S; abbreviated as SUS) were used, and each was formed into a base layer by sputtering about 60 nm on a PC substrate. As the metal oxide-based _{material, SiO 2, SnO 2, Ta} 2 O 5, with CeO ₂ and Al ₂ O _3, these IAD method (ion irradiation conditions 400~500V voltages applied at the time of beam irradiation of the ion gun And about 50 nm each on the PC substrate with an irradiation output of 300 W or less (irradiation at a current of 0.5 to 0.75 A) to form a base layer. Next, titanium oxide was vapor-deposited on the surface of each base layer by the procedures (1) to (7) of Example 1 to prepare a sample as a photocatalytic composite thin film.

Next, the PC board protection effect of these samples was confirmed. Specifically, black light (1 ± 0.2 mW / cm ² ) ultraviolet rays were continuously irradiated on the surface of each sample, and each sample was visually observed every week until one month later. No changes such as discoloration and deformation were observed on the substrate.

Next, the adhesion effect was confirmed. In order to examine the adhesion of each sample, it was put in a steam at 90 ° C., taken out after 5 hours and 24 hours, and the sample was visually observed. These results are shown in Table 3.

According to Table 3, in the observation after 5 hours, except for the sample using Al ₂ O ₃ as the base layer, the adhesion is excellent, and in the observation after 24 hours, chromium, titanium, SUS, SnO ₂ are used as the base layer. It shows that the used sample is excellent in adhesion. Any base layer other than Al ₂ O ₃ can be used, but SnO ₂ is particularly preferable in view of durability.

It is one conceptual diagram of the vapor deposition apparatus used for the manufacturing method of the amorphous titanium oxide thin film of this invention. It is an example of sectional drawing of the hydrophilic thin film by this invention. It is a graph which shows the X-ray-diffraction measurement result of the sample of Example 1 and Comparative Examples 1,3,4. It is a graph which shows the Raman spectroscopic analysis measurement result of the sample of Example 1 and Comparative Examples 1, 3, and 4. It is a graph which shows the result of apply | coating oil to the sample of Example 1 and Comparative Examples 1-4, and measuring the water droplet contact angle for every time passage. It is a graph which shows the result of having formed the silicon oxide layer in the sample of Example 1 and Comparative Examples 1 and 2, and measuring a water droplet contact angle for every time passage. It is a graph which shows the water droplet contact angle of the titanium oxide layer formed into a film by changing the beam voltage of an ion gun. It is a graph which shows the water droplet contact angle of the titanium oxide layer formed into a film by changing the beam current of an ion gun. It is a graph which shows the amount of radicals of the sample of Example 1 and Comparative Examples 1 and 4.

Explanation of symbols

1: vacuum chamber 2: electron gun 3: hearth 4: vapor flow 5: ion gun 6: ion beam 7: substrate 8: jig 9: heater 10: shutter 20: substrate 21: base layer 22: titanium oxide layer 23: Silicon oxide layer

Claims (6)

  A method for forming an amorphous titanium oxide thin film having photocatalytic performance, wherein a titanium oxide film is formed on a substrate while irradiating a vapor stream of titanium oxide on the substrate or during vapor deposition with an ion beam.   2. The method of forming an amorphous titanium oxide thin film having photocatalytic performance according to claim 1, wherein the ion beam has an applied voltage of 300 V or more and an irradiation output of 300 W or less.   The method for forming an amorphous titanium oxide thin film having photocatalytic performance according to claim 1 or 2, wherein a heating temperature of the substrate is 150 ° C or lower.   A photocatalytic composite thin film comprising a substrate, a base layer made of a metal, a metal oxide, or a mixture thereof provided on the substrate, and an amorphous titanium oxide layer having a photocatalytic function provided on the base layer The amorphous titanium oxide layer is a photocatalytic composite thin film formed on a substrate or while irradiating a vapor stream of titanium oxide with an ion beam.   A hydrophilic photocatalytic composite thin film having antifogging or self-cleaning properties, comprising a silicon oxide layer on the titanium oxide layer of the photocatalytic composite thin film of claim 4.   The photocatalytic composite thin film according to claim 5, wherein the silicon oxide layer has a thickness of 5 to 30 nm.

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