JP2012115753A - Titanium oxide-based material which has visible light-responsivity and excellent photocatalytic activity - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a titanium oxide-based material which has visible light-responsivity and excellent photocatalytic activity.SOLUTION: The titanium oxide-based material includes anatase-type titanium dioxide and titanium which binds to a hydroxyl group. In addition, the titanium oxide contains nitrogen and carbon, which constitute a Ti-C-Ti-O or Ti-N-Ti-O bond, in an amount of 0.01-40 mass% in total.

Description

  The present invention relates to a titanium oxide material having visible light responsiveness and excellent photocatalytic activity.

  There are many products on the market that exhibit antibacterial, anti-odor, and contamination resistance using the photocatalytic activity of titanium dioxide. Further, Patent Document 1 discloses that photocatalytic activity is exhibited by combining a anodic oxidation method and heating in an oxidizing atmosphere using a titanium base material. Furthermore, Patent Document 2 discloses a titanium-based metal material having excellent photocatalytic activity by laminating a titanium oxide powder-containing film on an anodized layer.

These titanium oxide-based materials having photocatalytic activity can be used in various corrosive environments because the base material is extremely excellent in corrosion resistance, and can be used in various applications such as building materials, vehicle exterior materials, It is processed into various shapes according to household appliances and the like.
Patent Document 3 discloses that titanium oxide is formed as a network structure and is used for purification, sterilization, etc. of seawater, sewage, fresh water, etc., using its photocatalytic activity.
Furthermore, Patent Document 4 and Patent Document 5 disclose that titanium particles having photocatalytic activity are obtained by performing anodizing treatment in a bath to which titanium oxide powder is added, and have these photocatalytic activities. Titanium particles are used for improving the stain resistance and antibacterial properties of various base materials by applying in combination with a binder.

JP-A-8-246192 JP-A-10-121266 JP 2008-187910 A JP 2002-38298 A JP 2003-129290 A

  The inventors anodized pure titanium according to Patent Document 1 and then heated to the atmosphere to produce titanium oxide on the substrate. However, sufficient photocatalytic activity was not obtained. In Patent Document 2, the titanium oxide-containing powder laminated on the anodized titanium layer is laminated, but this is presumed to be because high photocatalytic activity cannot be obtained by a simple combination of anodization and atmospheric heating. The However, stacking a titanium oxide layer after anodic oxidation as in Patent Document 2 is problematic from the viewpoint of adhesion. Furthermore, the cost increases because the titanium oxide-containing powder is laminated.

Furthermore, since the above titanium-based material has insufficient adhesion of the titanium oxide film formed on the base material by anodization, the base material- Peeling is likely to occur between the anodic oxide films, and as a result, it has been difficult to perform a molding process according to the application.
In addition, since the photocatalytic activity of titanium oxide is usually exhibited by ultraviolet irradiation, the titanium oxide of a network structure used in an underwater environment such as Patent Document 3 and the titanium particles of Patent Documents 4 and 5, sunlight, In the light irradiation by a lighting fixture, since there was little ultraviolet-ray amount, there also existed a problem that the photocatalytic activity could not fully be exhibited.

  In order to solve such a problem, the present inventors have previously described a titanium oxide-based material containing anatase-type titanium dioxide, further containing titanium bonded to a hydroxyl group in titanium oxide, By containing carbon, a titanium-based material having excellent adhesion between the base material and the titanium oxide layer, having visible light response and excellent photocatalytic activity, and oxidation having visible light response and excellent photocatalytic activity Titanium particles have been invented and a patent application (PCT / JP2010 / 059583) has been filed for the invention. However, an object of the present invention is to provide a titanium oxide-based material that is further superior in terms of photocatalytic activity.

As a result of further investigation focusing on the carbon and nitrogen in the titanium oxide discovered by the previous invention, the present invention has been found to result in a Ti—C—Ti—O bond or Ti—N—Ti— in titanium oxide. It was newly found that nitrogen and carbon forming an O bond are important for photocatalytic activity.
The gist of the present invention made based on the results is as follows.

(1) A titanium oxide-based material containing anatase-type titanium dioxide and titanium bonded to a hydroxyl group, and further, Ti—C—Ti—O bond or Ti—N—Ti—O bond is added to titanium oxide. A titanium oxide-based material having visible light responsiveness and excellent photocatalytic activity, comprising a total of 0.01 to 40% by mass of formed nitrogen and carbon.
(2) In the titanium oxide material according to (1), the titanium oxide material has a thickness of 0.1 μm to 5.0 μm by anodizing treatment on the surface of a base material made of pure titanium or a titanium alloy. A titanium oxide material characterized by being formed as a layer in a range.
(3) The titanium oxide material according to (2), wherein the base material is a plate-like body.
(4) The titanium oxide material according to the above (2), wherein the base material is a linear body.
(5) The titanium oxide material according to the above (1), wherein the titanium oxide material is formed as particles having a particle size in the range of 0.01 μm to 10 μm. material.

The titanium oxide-based material according to the present invention has visible light responsiveness and excellent photocatalytic activity.
The titanium oxide-based material of the present invention can be formed as a titanium oxide layer on pure titanium or a titanium alloy substrate by anodizing treatment. In that case, the adhesion between the titanium oxide layer and the substrate is good. Yes, when processing such as press molding is performed, the titanium oxide layer does not peel off and can be processed into various shapes according to the application.
In addition, the titanium oxide-based material according to the present invention can be formed as particles, and in that case, the titanium oxide particles can be applied in combination with various binders, even in an environment with a small amount of ultraviolet rays. Can exhibit excellent photocatalytic activity.

TiC, relative to the powder and the plate-shaped samples of the present invention the TiO 2 _(anatase) is a schematic diagram showing an example of a result of obtaining the radial distribution of X-ray absorption fine structure (XAFS).

  As a result of diligent efforts to obtain titanium oxide excellent in photocatalytic activity, the present inventors include titanium bonded to anatase-type titanium dioxide and a hydroxyl group in titanium oxide, and further, a predetermined amount of nitrogen in titanium oxide. It was found that by containing carbon, titanium oxide having visible light responsiveness and extremely excellent photocatalytic activity could be obtained, and the titanium oxide was formed as a layer on a substrate made of pure titanium and a titanium alloy. A patent application was previously filed as a titanium-based material or a titanium-based material formed as titanium oxide particles.

  In the present invention, as a result of further investigation focusing on nitrogen and carbon contained in titanium oxide, Ti-C-Ti-O bond or Ti-N-Ti-O bond in titanium oxide out of nitrogen and carbon. It is a new feature that it has been found that the nitrogen and carbon forming the carbon greatly affect the improvement of the photocatalytic activity.

  Therefore, first, anatase-type titanium dioxide and titanium oxide containing titanium bonded to a hydroxyl group, which are the basis of the present invention, will be described, and then the forms of nitrogen and carbon in the titanium oxide will be described.

In order to improve the photocatalytic activity, it is necessary that anatase-type titanium dioxide is present in titanium oxide as in the conventional case.
Further, it is necessary that titanium bonded to a hydroxyl group be present in the titanium oxide layer or titanium oxide particles.
The reason why titanium bonded to a hydroxyl group is necessary for improving photocatalytic activity is not clarified at present, but only the conventional anatase type titanium dioxide is completely different from the conventional knowledge required for improving photocatalytic activity. .

The presence of anatase-type titanium dioxide in the titanium oxide-based material is measured as follows using X-ray diffraction.
(1) When the titanium oxide-based material is formed as a layer on the substrate, X-ray diffraction of the sample is performed under the following conditions.
X-ray: Cu / 50kV / 200mA
Goniometer: RINT1000 Wide-angle goniometer Attachment: Rotating specimen stand for thin film Filter: Not used Incident monochrome: Not used Counter monochrometer: Fully automatic monochromator Diverging slit: 0.2mm
Divergence length restriction slit: 5mm
Receiving slit: Open Scattering slit: Open Counter: Scintillation counter (SC50)
Scan mode: Continuous Scan speed: 2.000 ° / min
Sampling width: 0.010 °
Scanning axis: 2θ
Scanning range: 10.000-100.000 °
Fixed angle: 1.500 °
In the obtained diffraction pattern, it is judged that the anatase type titanium dioxide exists when the peak (2θ = 25.281 degrees) of the (101) plane of the anatase type titanium dioxide is obtained at least 20 counts / second or more.

(2) When titanium oxide is formed as particles, X-ray diffraction is performed using a powder sample under the following conditions.
X-ray: Cu / 40kV / 150mA
Goniometer: RINT1000 Wide-angle goniometer Attachment: 43 sample changer (horizontal)
Filter: Not used Incident monochrome: Not used Counter monochromator: Fully automatic monochromator Divergence slit: 1 °
Scattering slit: 1 °
Receiving slit: 0.15mm
Monochrome light receiving slit: 0.8mm
Counter: Scintillation counter (SC50)
Scanning mode: Continuous Scanning speed: 5.000 ° / min
Sampling width: 0.020 °
Scanning axis: 2θ / θ
Scanning range: 5.000-100.000 °
θ offset: 0.000 °
In the obtained X-ray diffraction pattern, it is determined that anatase-type titanium dioxide exists when the peak (2θ = 25.281 degrees) of the (101) plane of anatase-type titanium dioxide is obtained at least 100 counts / second or more.

As in the case of anatase-type titanium dioxide, the verification of the presence of titanium bonded to a hydroxyl group in titanium oxide-based materials is also divided into the case of being formed as a layer and the case of being formed by particles. Do as follows.
The method for verifying the presence of titanium bonded to a hydroxyl group in the titanium oxide layer is that hydrogen is detected in the oxide film from the same position as oxygen and titanium using a glow discharge emission spectrometer or a secondary ion mass spectrometer. And if it is at least 5 times the hydrogen concentration of the titanium substrate, it is judged that hydrated titanium dioxide is formed.

The verification method of the titanium combined with hydroxyl groups in the titanium oxide particles are present, XPS (X -ray P hotoelectron S pectroscopy, abbreviated as hereinafter XPS) using analysis. And in the Ols spectrum obtained by performing surface measurement by XPS, a shoulder is observed in the vicinity of 531.5 to 532 eV because the peak due to the bonding of hydroxyl groups overlaps the high energy side of the peak at 530 eV due to TiO _2. Therefore, by analyzing the waveform of the spectrum, it can be seen that there is titanium bonded to a hydroxyl group.

Furthermore, it is necessary for titanium oxide to contain nitrogen and carbon.
In the previous patent application, the present inventors have found that it is advantageous for the photocatalytic activity that carbon or nitrogen is present in at least one of titanium carbide and titanium nitride in titanium oxide. As a result of further research, when carbon or nitrogen takes a Ti-C-Ti-O or Ti-N-Ti-O bond state apart from the presence or absence of titanium carbide or titanium nitride Was found to exhibit extremely excellent photocatalytic activity, leading to the present invention.

It has been confirmed that photocatalytic activity is significantly improved by including carbon and nitrogen in the form of Ti—C—Ti—O bonds or Ti—N—Ti—O bonds in titanium oxide materials. It is a completely new phenomenon that has not been reported to.
For example, according to Japanese Patent Application Laid-Open No. 2005-240139, etc., after titanium oxide is formed on the surface of titanium or a titanium alloy by PVD, CVD, thermal spraying, etc., it is preferably anodized in an electrolytic solution containing sulfuric acid and phosphoric acid. However, there is no knowledge about the presence of carbon and nitrogen in the anodized film, and there is no knowledge about visible light responsiveness.
Further, according to Japanese Patent No. 3601532 and Japanese Patent Application Laid-Open No. 2005-254128, it is known that titanium oxide is doped with nitrogen or further carbon or the like to develop a photocatalytic action in the visible light region. There is no hydrated titanium dioxide, and the presence of nitrogen and carbon is not particularly examined, so that it cannot be said that the visible light response is sufficient.

The present inventors first investigated the structure of titanium in titanium oxide in order to investigate the existence state of carbon or nitrogen in titanium oxide.
The experimental methods to investigate the concentration of titanium having a structure and a particular structure of titanium in titanium oxide, XAFS (X -ray- A bsorption F ine S tructure: X -ray absorption fine structure) is.

This XAFS is based on the following principle.
When the absorptance of the material is measured while increasing the X-ray energy, the X-ray energy decreases correspondingly. However, there is X-ray energy whose absorptance rapidly increases at certain X-ray energy (X-ray absorption edge) specific to the material. At this time, some of the photoelectrons generated by the X-ray absorption are reflected as structural information on the X-ray absorption amount by scattering and interference by a plurality of atoms. That is, information on the atomic structure can be obtained by monitoring the amount of X-ray absorption. (For example, Yasuo Udagawa, X-ray absorption fine structure, Academic Publishing Center (1993)). This is the principle of structural analysis by the XAFS method, and when this is used, the structure of titanium in titanium oxide can be obtained.

Next, a method for obtaining the structure of titanium in titanium oxide using structural analysis by the XAFS method will be specifically described.
When a substance is placed on the X-ray beam line, the substance is determined from the intensity of the X-ray (incident X-ray: I ₀ ) irradiated to the substance and the intensity of the X-ray (transmitted X-ray: I _t ) passing through the substance. X-ray absorption amount (X-ray absorption coefficient) is calculated. When X-ray energy (wavelength) is changed while monitoring the increase / decrease in the X-ray absorption coefficient and the X-ray absorption spectrum is measured, a sharp rise (absorption edge) of the X-ray absorption coefficient is observed at a certain energy position. Since the energy position of the absorption edge is specific to the element, if structural information can be extracted in the energy region near the absorption edge, it means that the information is specific to the element.

When an X-ray absorption spectrum is measured with sufficient accuracy in the energy region near the absorption edge of titanium element, fine structural vibration with attenuation is observed in the energy region of several hundreds eV from the absorption edge. . This extended X-ray absorption fine structure (EXAFS: E xtended X -ray- A bsorption F ine S tructure) and call and contains information about the local structure in the vicinity of the titanium element (atomic distance and coordination number) . When an EXAFS spectrum extracted from an X-ray absorption spectrum is subjected to Fourier transform in an appropriate region, a radial distribution function is obtained. This function is a one-dimensional distribution of electron density centered on the element of interest, and some atom is located at a distance showing the maximum value, and its intensity is proportional to the electron density of the atom located. Therefore, structural information about the element of interest can be obtained by numerically examining this radial distribution function.

On the other hand, in the energy region of several hundreds eV from the spectrum in the range of several 10 to 100 eV before and after the absorption edge, fine structural vibration accompanied by attenuation is observed. This X-ray absorption edge structure (XANES: X -ray A bsorption N ear- E dge S tructures) and call and contains information about the three-dimensional arrangement of atoms adjacent to the titanium atom. The structure of titanium in the sample is determined by comparing the XANES spectrum extracted from the X-ray absorption spectrum of the sample with the spectrum obtained by measuring the standard substance or the spectrum obtained by calculation from the model structure. It becomes possible.

The measurement is performed using a Si (111) channel cut monochromator as the spectral crystal, dividing the X-ray energy between 4959.5 eV and 5465.5 eV into four sections, scanning with an energy interval of 0.5 to 6 eV, and the transmission method or conversion electron yield. Done by law. If the sample is powder, the permeation method is used. The sample was mixed with BN and adjusted to an appropriate concentration, and the intensities of incident X-rays: I ₀ and transmitted X-rays: I _t passing through the sample were measured in an ion chamber. The integration time was 2 to 10 seconds / point. When the sample is plate-shaped, the conversion electron yield method is used. This is to measure the amount of Auger electrons generated when X-rays are absorbed by the sample. An X-ray permeable film in which aluminum is vapor-deposited is placed on the upper surface of the sample, and 500 V is placed between the sample and the film. The amount of Auger electrons is measured by applying an appropriate voltage.

When the structure of titanium in the titanium oxide of the present invention was determined by EXAFS and XANES, it was found that there was a peak different from TiO ₂ , TiC, and TiN measured as standard materials.
As a result of detailed examination, it was found that these peaks correspond to titanium atoms taking a Ti—C—Ti—O or Ti—N—Ti—O bond state. That is, the spectrum obtained by measuring EXAFS or XANES of a sample is peak-separated into a spectrum of a standard substance and a spectrum corresponding to the state of Ti—C—Ti—O or Ti—N—Ti—O bond. Thus, the concentration of carbon or nitrogen corresponding to the state of Ti—C—Ti—O or Ti—N—Ti—O bond can be determined.

  Therefore, when forming a titanium oxide layer containing anatase-type titanium dioxide and titanium bonded to a hydroxyl group, and further containing nitrogen and carbon on a titanium alloy substrate using an anodic oxidation method described later, a titanium alloy base material is used. The titanium oxide layers having different carbon and nitrogen concentrations are formed by changing the carbon concentration of the material or the heat treatment conditions in a nitrogen atmosphere, and the i-C- in titanium oxide obtained by the above method is used. The relationship between the concentration of carbon or nitrogen corresponding to the state of Ti—O or Ti—N—Ti—O bond and the photocatalytic activity was examined.

As a result, when the total concentration of carbon or nitrogen corresponding to the state of Ti—C—Ti—O or Ti—N—Ti—O bond is 0.01 wt% or more and 40 wt% or less, a sufficient photocatalyst It was found that activity was obtained.
This is because when the total concentration of carbon or nitrogen is 0.01% by weight or less, the ratio of Ti—C—Ti—O bonds or Ti—N—Ti—O bonds is small, and sufficient photocatalytic activity can be obtained. Because there is no. If the total concentration of carbon or nitrogen exceeds 40% by weight, the proportion of Ti—C—Ti—O bonds or Ti—N—Ti—O bonds increases so that a bulk TiC or TiN-like structure is obtained. It is assumed that sufficient photocatalytic activity cannot be obtained. From this point, a more preferable range of the total concentration is 0.01% by weight or more and less than 20% by weight.

  A more preferable range of the total concentration of nitrogen and carbon forming the Ti—C—Ti—O bond or Ti—N—Ti—O bond is 0.01% by mass or more and less than 1% by mass. This is because the amount of simple TiC and TiN precipitates that do not contribute to the Ti—C—Ti—O bond or Ti—N—Ti—O bond does not increase too much, and the Ti—C—Ti—O bond Alternatively, it does not adversely interact with Ti that contributes to the Ti—N—Ti—O bond.

Such a titanium oxide-based material is realized by forming it directly on the substrate as a layer or as particles.
In the case where the titanium oxide-based material is directly formed as a layer on the titanium substrate by using an anodic oxidation method described later, the thickness of the titanium oxide layer is 0.1 μm or more to obtain the above effects. 0 μm or less is preferable. If the thickness is less than 0.1 μm, sufficient photocatalytic activity cannot be expressed. On the other hand, when the thickness exceeds 5.0 μm, the photocatalytic activity value is almost saturated, and the adhesion between the substrate and the titanium oxide layer is lowered.

  The thickness of the titanium oxide layer is determined by measuring the element concentration distribution of titanium, oxygen, carbon, and nitrogen in the depth direction from the surface using a glow discharge emission spectrometer. Determined as thickness. For the identification of depth, after analysis, the depth obtained by glow discharge is measured using a stylus type surface roughness meter (resolution: 0.1 μm), and divided by the measurement time to quantitatively evaluate the depth. To implement.

When formed as particles, the particle size is in the range of 0.01 μm to 10 μm.
This is because when the particle size is less than 0.01 μm or more than 10 μm, the particles are not uniformly dispersed when applied as a slurry on the substrate.
Measurement of the particle diameter in the case of using particles can be performed using an electron microscope and X-rays. In addition, when X-rays are used, it is possible to measure to the sub-μm range, and in the case of particles smaller than that, it can be measured using an electron microscope.

In order to directly form the above titanium oxide-based material as a layer on a substrate, there is an anodic oxidation method using pure titanium or a titanium alloy as a substrate.
In the present invention, one of the characteristics is that titanium bonded to a hydroxyl group is contained. To form titanium bonded to a hydroxyl group, a method for forming a titanium oxide layer using an aqueous solution is required. The oxidation method is also suitable in this respect.
There is also an anodic oxidation method as a method of forming the titanium oxide particles as described above. In this case, a phenomenon in which titanium oxide is peeled off from the formed titanium oxide layer is used.

  The anodic oxidation method is an industrially established method, in which pure titanium or a titanium alloy is immersed in an appropriate aqueous solution having ion conductivity, and is chemically stable and conductive in the aqueous solution. A cathode plate (usually stainless steel) is immersed and various voltages are applied using titanium or a titanium alloy as an anode. Thus, the anodized film is a film of titanium oxide formed on the titanium surface in an aqueous solution, which is different from titanium oxide formed by a method that does not use an aqueous solution such as PVD, CVD, thermal spraying, and atmospheric oxidation. Yes.

  One or both of carbon and nitrogen are included in the anodized film or titanium oxide particles in a state in which carbon and nitrogen form an i-C-Ti-O bond or a Ti-N-Ti-O bond. For this purpose, there is a method in which one or both of carbon and nitrogen is previously contained in pure titanium or a titanium alloy base material used as an anode.

For example, there is a method of carburizing a surface layer (μm order range) of pure titanium or titanium alloy in advance, but in order to implement this method industrially, a material made of titanium or titanium alloy is thinned by cold rolling. Then, rolling is performed such that carbon resulting from the lubricating oil penetrates into titanium, and then a carburized layer is formed on the surface layer by heat treatment.
In addition, as a method applicable to titanium oxide particles, a carburized layer is formed on the surface layer of titanium or titanium alloy by applying carbon or an organic or inorganic compound containing carbon to the surface of titanium or titanium alloy and heat-treating it. There is.

In addition, after performing only the carburizing treatment, the titanium or titanium alloy is heated in a mixed gas atmosphere of nitrogen, nitrogen and other inert gas, or a gas that does not react with titanium or titanium alloy, Both nitriding layers may be made.
Further, only the carburizing treatment may be performed because it is possible to contain nitrogen in titanium oxide by anodizing in a solution containing nitrate ions having different concentrations.
Furthermore, without forming such a carburized layer or nitride layer, for example, when anodizing is performed on pure titanium and titanium alloy substrates pickled in a mixed acid solution of nitric acid and hydrofluoric acid, Since carbon and nitrogen are contained in the film, pure titanium and titanium alloy subjected to pickling finish may be used.

Anodization is performed using pure titanium or a titanium alloy having a carburized layer or a nitrided layer as described above as an anode and an appropriate metal as a cathode.
At that time, nitrogen and carbon containing anatase-type titanium dioxide and titanium bonded to a hydroxyl group, and forming a Ti—C—Ti—O bond or a Ti—N—Ti—O bond in titanium oxide. In order to form a titanium oxide layer and titanium oxide particles containing 0.01 to 40% by mass in total, anodization may be performed under the following conditions.

In order to obtain excellent photocatalytic activity by anodic oxidation, it is necessary to contain nitrate ions in the solution. In order to obtain such an effect, the nitrate ion concentration is preferably at least 0.01 M or more. Since nitrate ions are not adversely affected by increasing the addition amount thereof, the upper limit of the addition amount of nitrate ions is set to the saturated concentration of each nitrate.
Nitric acid ions can be added as an aqueous nitric acid solution or nitrate. Typical nitrates include sodium nitrate, potassium nitrate, lithium nitrate, and ammonium nitrate, but other metal nitrates may be used.

  It should be noted that there are many unclear points why anodized titanium exhibits excellent photocatalytic activity when nitrate ions are contained in the aqueous solution, which is a new finding that cannot be explained only by specific surface area, titanium oxide crystal structure, etc. . As described above, the upper limit of the nitrate ion addition amount is not particularly limited, and the effect can be exhibited up to the saturation concentration of each nitrate. In addition, the more preferable range of nitrate ion addition amount is 0.1 M or more and a saturated concentration.

As for the anodic oxidation voltage, when a titanium oxide layer is formed, it is preferable to apply an anodic oxidation voltage of at least 10 V and 30 seconds to 60 minutes.
When the anodic oxidation voltage is less than 10 V, a total of 0.01% by mass or more of nitrogen and carbon forming Ti—C—Ti—O bonds or Ti—N—Ti—O bonds is formed in titanium oxide. Cannot be obtained and excellent photocatalytic activity cannot be obtained. Moreover, even if the anodic oxidation time is less than 30 seconds, sufficient photocatalytic activity cannot be obtained, and a titanium oxide layer having a thickness of 0.1 μm or more cannot be formed. On the other hand, even if the anodization time exceeds 60 minutes, the thickness of the anodic oxide film to be formed hardly changes. Therefore, the anodization time of 60 minutes is sufficient.

Further, the appearance of the formed titanium oxide layer changes as follows depending on the anodizing voltage.
When the anodic oxidation voltage is 10 V or more and less than 18 V, it is possible to obtain a beautiful appearance of interference color as well as excellent photocatalytic activity.
When the anodic oxidation voltage is 18 V or more and less than 25 V, a calm amber appearance can be obtained with excellent photocatalytic activity. If it is less than 18V or 25V or more, a calm amber appearance cannot be obtained.
The anodic oxidation time at these voltages is not less than 30 seconds and not more than 60 minutes as described above. However, there is no problem even if the anodic oxidation is carried out over 60 minutes.

  When the anodic oxidation voltage is 25 V or more, a gray appearance with reduced lightness can be obtained with excellent photocatalytic activity. However, when the anodic oxidation voltage is 100 V or higher, partial dissolution of titanium occurs and the elution of titanium becomes remarkably significant, so the anodic oxidation voltage is set to less than 100 V. Also in this case, the anodic oxidation time is 30 seconds or more and 60 minutes or less. However, in this voltage region, since the elution of titanium itself is remarkable as described above, it is not preferable to anodize over 60 minutes.

The conditions for forming the titanium oxide particles by the anodic oxidation method are as follows.
As an anodizing voltage, it is necessary to apply at least 10 V or more. Titanium oxide particles are formed by peeling off the titanium oxide layer on the surface of pure titanium or titanium alloy used as the anode. When the anodic oxidation voltage is low, a long anodic oxidation time is required. It can be formed in a short anodic oxidation time as the voltage is increased.

  When the anodic oxidation voltage is less than 10 V, generation of titanium oxide particles does not occur on the surface of pure titanium or the like. In addition, since the produced titanium oxide particles remain on the surface of pure titanium or the like and precipitate in the solution, the titanium oxide particles can be obtained by separating the solution. A more preferable anode voltage range is 30 V or more and less than 100 V.

  Further, even if the anodization time is less than 30 seconds, sufficient photocatalytic activity cannot be obtained. On the other hand, when the anodization time exceeds 60 minutes, the elution of the titanium-based material itself becomes remarkable as described above. The upper limit is preferably 60 minutes. However, there is no problem even if anodization is performed for a longer time than this, but the upper limit is preferably 60 minutes from the viewpoint of yield reduction.

  In addition, since anodization is usually performed at room temperature, there is a fluctuation of about 5 ° C. to 30 ° C. in winter and summer, but in any case where a titanium oxide layer and titanium oxide particles are formed, the effect of temperature on the photocatalytic performance. There is no. In summer, the solution temperature may rise to nearly 50 ° C. due to Joule heat generation during anodic oxidation, but there is no adverse effect on the photocatalytic activity.

When anodizing in an aqueous solution containing nitrate ions, the photocatalytic activity can be further improved by a subsequent heat treatment in the atmosphere.
In order to exhibit such an effect, it is necessary to heat at a temperature of at least 200 ° C. after the anodizing treatment. However, if heated above 750 ° C., the photocatalytic activity decreases, so 750 ° C. is the upper limit.

  As for the heating time, a sufficient photocatalytic activity improving effect cannot be obtained unless heating is performed for at least 1 minute in the atmosphere. However, 24 hours is the upper limit because the effect of the photocatalytic activity is saturated even if heating is performed for more than 24 hours. This is an excellent photocatalytic activity that can be obtained for the first time by purely anodizing pure titanium or a titanium alloy in an aqueous solution containing nitrate ions. A more preferable heating temperature range is 300 ° C to 600 ° C.

  Moreover, the photocatalytic activity of the anodized material can be significantly improved by adjusting the pH of the aqueous solution containing nitrate ions to 12 or more and 15 or less. Although the detailed mechanism is unknown, the cation species when the aqueous solution is alkalinized does not have a great influence. Therefore, caustic soda, potassium hydroxide, lithium hydroxide, ammonium hydroxide or metal hydroxide may be used. However, if it exceeds pH 15, the performance of photocatalytic activity is saturated, and furthermore, a very strong alkaline solution causes problems from the viewpoint of work safety, so pH 15 is made the upper limit. The anodic oxidation voltage needs to be at least 10 V or more, but when it becomes 100 V or more, the dissolution reaction of titanium is remarkably promoted, so it is set to less than 100 V. The anodic oxidation time needs to be at least 30 seconds, but if it exceeds 60 minutes, the effect is saturated, so the upper limit is 60 minutes.

As a base material used when the titanium oxide layer of the present invention is formed by an anodic oxidation method, pure titanium (4 types from JIS 1), titanium alloys (11 types, 12 types, 13 types, 21 types, 60 types, 60E type, 61 type, ASTM Gr.12, etc. can be used.
Using such pure titanium and titanium alloy as a raw material, for example, after processing into a plate-like body or a linear body, anodizing treatment as described above has visible light responsiveness and excellent photocatalytic activity. A titanium oxide based material is obtained.

If the substrate of titanium oxide-based material is a plate or wire, it can be industrially mass-produced as a continuous long coil, and it can be used in various shapes depending on the application. Can be processed. In the case of a plate-like body, if it is further processed into a foil, application to the surface of an existing one becomes easy.
Moreover, what processed the base material into the shape according to a use beforehand, and then anodized may be used.
When a titanium oxide-based material is formed into a network structure, it can be made into a network structure using a linear material that has been previously anodized to impart photocatalytic activity, or a linear structure that has not been anodized. After the network structure is formed of the material, the entire network structure may be anodized to give a network structure with photocatalytic activity.
Furthermore, the net-like structure is not limited to one formed using a linear material, and may be an expanded metal produced by making a number of cuts in the plate-like body and pulling and expanding the plate-like body. .

  In the case of titanium oxide particles, pure titanium and titanium alloy as described above are used as materials, and anodizing treatment as described above is performed to obtain a titanium-based material having visible light responsiveness and excellent photocatalytic activity. .

Using pure titanium and various titanium alloys shown in Tables 1 to 4 as raw materials, a continuous long coil material was produced by cold rolling to a thickness of 1 mm, and in argon gas at each temperature from 570 ° C. to 700 ° C. without cleaning. Test substrates of pure titanium and various titanium alloy plates were prepared by changing the carbon concentration and carburized layer depth by heating for 5 hours.
Further, a part of the long coil material cold-rolled to the thickness of 1 mm is further cold-rolled to a thickness of 15 μm, and each temperature of 750 ° C. to 950 ° C. for 20 seconds to 70 seconds in an argon atmosphere or a nitrogen atmosphere. Test substrates of pure titanium foil and titanium alloy foil were produced by heat treatment for a period of time.

  Anodization is performed by applying a voltage of 24 to 80 V at room temperature for 2 minutes at a room temperature using a test substrate made of pure titanium and various titanium alloys as an anode and SUS304 steel as a cathode in an ammonium nitrate solution of 5 to 20 g / l. Samples were prepared in which the thickness of the oxide layer, the presence or absence of titanium bonded to anatase-type titanium dioxide and hydroxyl groups, and the nitrogen concentration and carbon concentration in the anodized film were changed.

In the titanium oxide layer formed on the surface of the titanium substrate, the concentrations of nitrogen and carbon forming Ti—C—Ti—O bonds or Ti—N—Ti—O bonds were determined by the following method.
Measurement is performed using a Si (111) channel cut monochromator as a spectral crystal, dividing the X-ray energy between 4959.5 eV and 5465.5 eV into four sections, scanning with an energy interval of 0.5 to 6 eV, and a transmission method. Alternatively, the conversion electron yield method was used.

In the case of powders of TiN, TiC, TiO ₂ (anatase type) which are standard samples, the permeation method was used. This measures the intensity of transmitted X-rays that have passed through the sample. After the sample is mixed with BN and adjusted to an appropriate concentration, incident X-rays: I ₀ and transmitted X-rays that have passed through the sample: I _t The intensity of each was measured in an ion chamber. The integration time was 2 to 10 seconds / point.

  In the case of a plate-like sample of the present invention, the conversion electron yield method was used. This is to measure the amount of Auger electrons generated when X-rays are absorbed by the sample. An X-ray permeable film in which aluminum is vapor-deposited is arranged on the upper surface of the sample, and 500 V is interposed between the samples. The amount of Auger electrons was measured by applying an appropriate voltage.

The radial distribution was determined from the X-ray absorption fine structure (XAFS) by the following procedure measurement.
The background is subtracted from the measured XAFS spectrum using the Victorian equation (Cλ ₃ −Dλ ₄ + Const.) With a constant term, and the absorbance of isolated atoms is estimated by the Cubic-Spline (weight) method and the EXAFS signal is extracted. Then, Fourier transformation was performed to obtain a radial distribution.

An example of the results obtained for the TiC, TiO ₂ (anatase type) powder and the plate-like sample of the present invention is schematically shown in FIG.
In FIG. 1, the first and second adjacent peaks of Ti atoms (indicated by downward arrows) in TiC and TiO ₂ can be clearly confirmed. The peak position represents the distance from the titanium atom to the adjacent atom, and the peak height represents the number of adjacent atoms or ligands.

In the spectrum of the plate-like sample of the present invention, peaks marked with * are clearly observed in addition to the peaks corresponding to the first and second neighboring peaks of Ti atoms in TiC and TiO ₂ .
This is a peak considered to be caused by Ti—C—Ti—O or Ti—N—Ti—O bond. That is, the spectrum of the plate-like sample of the present invention is defined as the sum of contributions from the peaks attributed to TiC and TiO ₂ and the peaks attributed to Ti—C—Ti—O or Ti—N—Ti—O bonds. By calculating and fitting the experimental spectrum and the calculated spectrum to be close, the atomic concentration of carbon or nitrogen taking the state of Ti—C—Ti—O or Ti—N—Ti—O bond in the total titanium is calculated. Can be sought.

The photocatalytic activity was evaluated as follows.
In the transparent plastic case with an upper lid, the above-mentioned various types of anode titanium cut into dimensions of 15 mm in width, 25 mm in length, and 0.4 mm in thickness are placed with the plate surface facing up. 50 g of 0.01 g / l methylene blue solution was put there, and the case was irradiated from the top with two 15 W black lights (Toshiba Lighting & Technology Co., Ltd., FL-15BLB-A) for 30 minutes. Absorbance at 667 nm was measured using a photometer (Hitachi: U-2910), the absorbance of the solution without the test piece was subtracted as a blank, and the value was used for evaluation of photocatalytic activity. The container containing the solution used at that time was a quartz cell having a thickness of 1.2 mm and a length of 10 mm.
In order to remove the background of the apparatus itself, at the time of measuring the absorbance, a similar cell containing distilled water was simultaneously measured to remove the background of the apparatus.

Said evaluation test was implemented in the room | chamber interior set to 20 degreeC. The visible light response was evaluated by attaching an ultraviolet shielding film to a transparent plastic case, confirming that the ultraviolet rays were shielded, and irradiating with two 15 W fluorescent lamps from the top for 300 minutes. The absorbance at 667 nm was measured using a meter, and the absorbance of only the solution without the test piece was subtracted as a blank, and the value was used for the evaluation of the photocatalytic activity. Said evaluation test was implemented in the room | chamber interior set to 20 degreeC. The background removal method of the used cell and apparatus was carried out in the same manner as described above.
In addition, after subtracting the light absorbency of a blank, when the numerical value became minus, it described in the table | surface as 0.00 for convenience.
When this numerical value is 0.00, it can be determined that there is no photocatalytic activity (responsiveness), and that 0.01 or more indicates that photocatalytic activity (responsiveness) is present.

Inventions A1 to A71 of Tables 1 to 3 are examples of the present invention.
From the results of Tables 1 to 3, anatase-type titanium dioxide and titanium bonded to a hydroxyl group exist, and a Ti—C—Ti—O bond or a Ti—N—Ti—O bond exists in the titanium oxide film. It can be seen that the present inventions A1 to A71 containing the total concentration of nitrogen and carbon forming these bonds between 0.01 to 40% by mass exhibit good photocatalytic activity. Among them, when the total concentration of nitrogen and carbon is 0.01 to 1% by mass (Invention A1, 2, 13, 14, 19, 20, 31, 32, 37, 38, 46, 47, 57, 58, 59, 64, 65) shows a further excellent photocatalytic activity. In both cases, as can be seen from the “photocatalyst evaluation test results (ultraviolet ray shielding and fluorescent lamp irradiation)”, visible light responsiveness was also exhibited.
In addition, in this Example, it was confirmed that the said effect is acquired in the range whose thickness of a titanium oxide layer is 0.1-5 micrometers.

  Table 4 is a comparative example for the present invention. When no anatase-type titanium dioxide is present in the titanium oxide layer (Comparative Example B4), or when no Ti—C—Ti—O bond or Ti—N—Ti—O bond is present in the titanium oxide layer (Comparative Examples B1, B4) ), When the total concentration of nitrogen or carbon forming Ti—C—Ti—O bond or Ti—N—Ti—O bond is less than 0.01% (Comparative Examples B1 to B3), the total concentration is When it exceeds 40% (Comparative Example B4), it can be seen that no photocatalytic activity occurs.

  In addition, when the adhesive test was implemented about the plate-shaped material in which the titanium oxide layer of this invention was formed, it has confirmed that peeling of a titanium oxide layer does not arise in any case.

Using pure titanium and various titanium alloy plates and foils shown in Tables 5 to 8 as raw materials, the carbon concentration and the carburized layer depth were changed by heating in argon gas at each temperature from 570 ° C. to 700 ° C. for 5 hours. Prepared materials.
Anodization bonds with hydroxyl groups by applying a voltage of 24 to 80 V at room temperature for 2 to 10 minutes at room temperature using pure titanium and various titanium alloys as an anode and SUS304 steel as a cathode in an ammonium nitrate solution of 5 to 20 g / l. Further, titanium oxide particles further containing anatase-type titanium dioxide and in which the nitrogen concentration and carbon concentration in the titanium oxide particles were changed were produced, and this was prepared as a sample.

  The concentration of nitrogen and carbon forming the Ti—C—Ti—O bond or Ti—N—Ti—O bond in the titanium oxide particles was the same as in Example 1 using the transmission method in the same manner as in the standard sample. Determined by the method.

  The photocatalytic activity was evaluated by attaching 40 mg of titanium oxide particles produced by an anodic oxidation method to the adhesive surface of a 15 mm × 25 mm adhesive tape, and placing it in a transparent plastic case with an upper lid with the adhesion surface facing upward. 50 ml of a 0.1M potassium iodide solution is placed in the top, and two 15 W black lights (FL-15BLB-A, manufactured by Toshiba Lighting & Technology Co., Ltd.) are irradiated for 30 minutes from the top. After irradiation, a spectrophotometer ( The absorbance at 287 nm was measured using Hitachi: U-2910), the absorbance of the solution without the test piece was subtracted as a blank, and the value was used for the evaluation of the photocatalytic activity. The container containing the solution is a quartz cell having a thickness of 1.2 mm and a length of 10 mm. In order to remove the background of the apparatus itself, at the time of measuring the absorbance, a similar cell containing distilled water was simultaneously measured to remove the background of the apparatus.

Said evaluation test was implemented in the room | chamber interior set to 20 degreeC. The visible light response was evaluated by attaching an ultraviolet shielding film to a transparent plastic case, confirming that the ultraviolet rays were shielded, and irradiating two 15 W fluorescent lamps from the top for 300 minutes. The absorbance at 287 nm was measured using a meter, and the absorbance of only the solution without the test piece was subtracted as a blank, and the value was used for evaluation of photocatalytic activity. Said evaluation test was implemented in the room | chamber interior set to 20 degreeC. The background removal method of the used cell and apparatus was carried out in the same manner as described above.
In addition, after subtracting the light absorbency of a blank, when the numerical value became minus, it described in the table | surface as 0.00 for convenience. When this numerical value is 0.00, it can be determined that there is no photocatalytic activity (responsiveness), and that 0.01 or more indicates that photocatalytic activity (responsiveness) is present.

Inventions A72 to A142 in Tables 5 to 7 are examples of the present invention.
From the results of Tables 5 to 7, anatase-type titanium dioxide and titanium bonded to a hydroxyl group are present, and Ti-C-Ti-O bond or Ti-N-Ti-O bond is present in the titanium oxide particles. It turns out that this invention A72-A141 which contains the total density | concentration of nitrogen and carbon which forms those coupling | bondings between 0.01-40 mass% shows favorable photocatalytic activity. Among them, when the total concentration of nitrogen and carbon is 0.01 to 1% by mass (Invention A72, 73, 84, 85, 90, 91, 101 to 103, 108, 109, 117, 118, 128 to 130, 135, 136) show even better photocatalytic activity. In each case, visible light responsiveness was also shown, as can be seen from the “photocatalyst evaluation test results (ultraviolet ray shielding and fluorescent lamp irradiation)”.
In addition, in this Example, it was confirmed that the said effect is acquired in the range whose titanium oxide particle diameter is 0.01-10 micrometers.

The titanium oxide-based material of the present invention has visible light responsiveness and exhibits excellent photocatalytic activity, and is therefore suitable for applications such as stain resistance and antibacterial properties, and is applicable in the building materials, medical fields, and water treatment fields. Suitable for
When the titanium oxide-based material of the present invention is formed as a plate-like body, it has excellent adhesion to the base material, so it can be formed into any shape by processing, and a wider range of fields Can be applied to. Further, when the plate-like body is a net-like structure, it has a visible light responsiveness and exhibits excellent photocatalytic activity, and thus is suitable for uses such as purification, sterilization, and the like of seawater, sewage, and fresh water.
When the titanium oxide-based material of the present invention is formed as titanium oxide particles, it can be applied regardless of the type of substrate by combining with a binder, and can be applied to a wider range of fields.

Claims (5)

  A titanium oxide-based material containing anatase-type titanium dioxide and titanium bonded to a hydroxyl group, and further, Ti—C—Ti—O bond or Ti—N—Ti—O bond is formed in the titanium oxide. A titanium oxide-based material having visible light responsiveness and excellent photocatalytic activity, containing a total of 0.01 to 40% by mass of nitrogen and carbon.   2. The titanium oxide-based material according to claim 1, wherein the titanium oxide-based material is formed as a layer having a thickness in the range of 0.1 μm to 5.0 μm on the surface of a base material made of pure titanium or a titanium alloy. A titanium oxide-based material characterized in that   The titanium oxide-based material according to claim 2, wherein the base material is a plate-like body.   3. The titanium oxide material according to claim 2, wherein the base material is a linear body.   The titanium oxide-based material according to claim 1, wherein the titanium oxide-based material is formed as particles having a particle diameter in a range of 0.01 µm to 10 µm.

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