JP2009067655A - NANOCRYSTAL-ACCUMULATED TiO2 AND ITS PRODUCING METHOD - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide nanocrystal-accumulated TiO<SB>2</SB>, its producing method and an anatase TiO<SB>2</SB>-based device product. <P>SOLUTION: The nanocrystal-accumulated TiO<SB>2</SB>deposited by a solution reaction system to deposit a titanium oxide crystal and having a nanocrystal consisting of an anatase TiO<SB>2</SB>single phase, an acicular crystal grown from the center of a particle to an outward side along c-axis, an edge part of the acicular crystal constituted of the anatase TiO<SB>2</SB>single phase and a structure exposing an anatase TiO<SB>2</SB>crystal on a surface is provided. The producing method of the nanocrystal-accumulated TiO<SB>2</SB>deposited on a substrate or in a solution comprising that an acicular TiO<SB>2</SB>nanocrystal is formed in a liquid phase on the substrate or in the solution by using the solution reaction system to deposit the titanium oxide crystal, the growing condition of the nanocrystal in a thin white solution specifically realized in an early stage of a reaction is utilized and the generated acicular TiO<SB>2</SB>nanocrystal is accumulated and its device product are provided. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

The present invention relates to nanocrystal-integrated TiO ₂ particles or nanocrystal-integrated TiO ₂ films, a method for producing the same, and a device product thereof. More specifically, the present invention relates to particles containing anatase-type TiO ₂ crystals (molar ratio 30). %), A particle film containing anatase TiO ₂ crystals (molar ratio of 30% or more), a production method thereof, and a device product thereof.

The present invention is applicable to, for example, a nanocrystal integrated TiO _{2 that} can be suitably used as a photocatalyst, cosmetics, dye-sensitized solar cell, molecular sensor, gas sensor, solution sensor, antifouling coating, antifogging coating, superhydrophilic surface coating, and the like (Nano-TiO ₂ crystal aggregate) and its manufacturing method are provided.

Nanoporous TiO ₂ having micropores (<2 nm), mesopores (2 nm to 50 nm), and macropores (> 50 nm) has attracted attention from both basic science and technical applications. In application, for example, cosmetics, catalyst (Non-patent Document 1), photocatalyst (Non-Patent Document 2-4), gas sensor (Non-Patent Documents 5 and 6), lithium battery (Non-Patent Document 7-9), living body Expectations are increasing for molecular sensors (Non-Patent Document 10), dye-sensitized solar cells (Non-Patent Documents 11 and 12), and the like.

In photocatalysts, biomolecular sensors, and dye-sensitized solar cells, anatase TiO ₂ has higher characteristics than rutile TiO ₂ . In these applications, in order to realize high efficiency or high sensitivity, TiO ₂ having a high surface area is strongly demanded. In addition, biomolecule sensors and dye-sensitized solar cells are required to have a nano / micro-sized uneven structure on the surface in order to adsorb many dyes, molecules or DNA.

Conventionally, TiO ₂ nanoparticles have been used for flame synthesis (Non-Patent Documents 13 and 14), ultrasonic synthesis (Non-Patent Documents 15 and 16), chemical vapor synthesis (non-patent documents) (non-patent documents 13 and 14). Patent Document 17) or sol-gel methods (Non-Patent Documents 2, 18-21) and the like.

As described above, conventionally, nanoporous TiO ₂ having micropores (<2 nm), mesopores (2 nm to 50 nm), and macropores (> 50 nm) has attracted attention from both basic science and technical applications. Further, in terms of applications, expectations are increasing for cosmetics, catalysts, photocatalysts, gas sensors, lithium batteries, biomolecular sensor dye-sensitized solar cells, and the like. In photocatalysts, biomolecular sensors, and dye-sensitized solar cells, anatase TiO ₂ has higher characteristics than rutile TiO ₂ .

Further, as described above, TiO ₂ nanoparticles may be produced by flame synthesis, ultrasonic synthesis, chemical vapor synthesis, sol-gel methods, or the like. Has been synthesized. However, the high temperature heat treatment in the synthesis process has a problem that the nanoparticles are aggregated and the surface area is reduced. In these processes, it was difficult to give a nano-sized uneven structure on the particle surface.

  On the other hand, surfactants (surfactants), chelating agents (chelating agents), soft polymers such as block polymers (non-patent documents 22-25), porous anionic aluminate (porous anionic alumina), porous Of high surface area porous materials using porous materials using hard templates (non-patent documents 26, 27) such as porous silica, polystyrene particles (polystyrene spheres), and carbon nanotubes (carbon nanotubes) are reported. Has been.

However, these conventional techniques have a problem that the nanostructure is inevitably changed in the heat treatment step for crystallization from amorphous TiO ₂ to anatase TiO ₂ . This means that the nanostructure on the surface is damaged by the change of the nanostructure during the heat treatment and the surface area is reduced. Therefore, in this technical field, it has been strongly demanded to develop a technique for producing nano-TiO ₂ crystals that do not cause nanostructure change by such heat treatment.

Carlson, T .; Giffin, G .; L. , J .; Phys. Chem. 1986, 90, (22), 5896-5900 Zhang, Z .; B. Wang, C .; C. Zakaria, R .; Ying, J .; Y. , Journal of Physical Chemistry B 1998, 102, (52), 10871-10878. Wang, R.A. Hashimoto, K .; Fujishima, A .; , Nature 1997, 388, (6641), 431-432. Choi, W .; Y. Termin, A .; Hoffmann, M .; R. , Journal of Physical Chemistry 1994, 98, (51), 13669-13679. Kumazawa, N .; Islam, M .; R. Takeuchi, M .; , Journal of Electroanalytical Chemistry 1999, 472, (2), 137-141. Ferroni, M .; Carotta, M .; C. Guidi, V .; Martinelli, G .; Ronconi, F .; Sacerdoti, M .; Traversa, E .; , Sensors and Actuators B-Chemical 2001, 77, (1-2), 163-166. Wagemaker, M.M. Kentgens, A .; P. M.M. Mulder, F .; M.M. , Nature 2002, 418, (6896), 397-399. Arico, A.M. S. Bruce, P .; Scrosati, B .; Tarascon, J .; M.M. Van Schalkwijk, W .; , Nature Materials 2005, 4, (5), 366-377. Guo, Y. et al. G. Hu, Y .; S. Maier, J .; , Chemical Communications 2006, (26), 2783-2785. Tokyo, H.C. Yamada, Y .; Sonezaki, S .; Ishikawa, H .; Bekki, M .; Kanehira, K .; Miyauchi, M .; , Applied Physics Letters 2005, 87, (21). Nazeeruddin, M .; K. De Angelis, F .; Fantacci, S .; Selloni, A .; Viscardi, G .; Liska, P .; Ito, S .; Takeru, B .; Gratzel, M .; G. , Journal of the American Chemical Society 2005, 127, (48), 16835-16847. Wang, P.A. Zakeeruddin, S .; M.M. Moser, J .; E. Humphry-Baker, R .; Comte, P .; Aranyos, V .; Hagfeldt, A .; Nazeeruddin, M .; K. Gratzel, M .; , Advanced Materials 2004, 16, (20), 1806-1811. Morrison, P.M. W. Raghavan, R .; Timpone, A .; J. et al. Artelt, C .; P. Pratsinis, S .; E. , Chemistry of Materials 1997, 9, (12), 2702-2708. Yang, G .; X. Zhuang, H .; R. Biswas, P .; , Nanostructured Materials 1996, 7, (6), 675-689. Yu, J .; C. Yu, J .; G. Ho, W .; K. Zhang, L .; Z. , Chemical Communications 2001, (19), 1942-1943. Huang, W.H. P. Tang, X .; H. Wang, Y .; Q. Koltypin, Y .; Gedanken, A .; , Chemical Communications 2000, (15), 1415-1416. Seifried, S .; Winterer, M .; Hahn, H .; , Chemical Vapor Deposition 2000, 6, (5), 239-244. Scolan, E .; Sanchez, C .; , Chemistry of Materials 1998, 10, (10), 3217-3223. Wang, C.I. C. Ying, J .; Y. , Chemistry of Materials 1999, 11, (11), 3113-3120. Burnside, S.M. D. Shklover, V .; Barbe, C .; Comte, P .; Arendse, F .; Brooks, K .; Gratzel, M .; , Chemistry of Materials 1998, 10, (9), 2419-2425. Zhang, H .; Z. Finnegan, M .; Banfield, J .; F. , Nano Letters 2001, 1, (2), 81-85. Choi, S .; Y. Mamak, M .; Coombs, N .; Chopra, N .; Ozin, G .; A. , Advanced Functional Materials 2004, 14, (4), 335-344. Antonelli, D.A. M.M. Ying, J .; Y. , Angelwandte Chemie-International Edition in English 1995, 34, (18), 2014-2017. Shibata, H .; Ogura, T .; Mukai, T .; Ohkubo, T .; Sakai, H .; Abe, M .; , Journal of the American Chemical Society 2005, 127, (47), 16396-16397. Shibata, H .; Mihara, H .; Mlikai, T .; Ogura, T .; Kohno, H .; Ohkubo, T .; Sakait, H .; Abe, M .; , Chemistry of Materials 2006, 18, (9), 2256-2260. Tian, B.B. Z. Liu, X .; Y. Yang, H .; F. Xie, S .; H. Yu, C .; Z. Tu, B .; Zhao, D .; Y. , Advanced Materials 2003, 15, (16), 1370- +. Ryoo, R .; Joe, S .; H. Kruk, M .; Jaroniec, M .; , Advanced Materials 2001, 13, (9), 677-681.

Under such circumstances, the present inventors have aimed to develop a technology for synthesizing nanocrystalline TiO ₂ particles that realizes solving the above-mentioned problems in view of the above-described conventional technology. As a result of intensive research, the inventors succeeded in synthesizing a new nanocrystalline TiO ₂ capable of synthesizing anatase TiO ₂ under a low temperature condition of 50 ° C. without requiring high-temperature heat treatment. It came to be completed. An object of the present invention is to provide nanocrystal-integrated TiO ₂ particles and nanocrystal-integrated TiO ₂ particle films, methods for producing the same, and device products thereof.

The present invention for solving the above-described problems comprises the following technical means.
(1) Nanocrystal-integrated TiO ₂ deposited on a substrate or in a solution in a solution reaction system for depositing titanium oxide crystals, 1) the nanocrystal is composed of anatase TiO ₂ single phase, and 2) from the particle center It has a needle-like crystal grown along the c-axis on the outside. 3) The tip of the needle-like crystal is also composed of a single phase of anatase TiO _2. 4) The anatase TiO ₂ crystal is exposed on the surface. Nanocrystalline integrated TiO ₂ , characterized in that
(2) the surface and the interior of the particle, is realized open pores and uneven surface structure of the nano-sized nanocrystals integrated TiO ₂ according to (1).
(3) The nanocrystal integrated TiO _{2 according to} (1) or (2), wherein the substrate is a glass, silicon, metal, ceramic, or polymer substrate.
(4) The nanocrystal integrated TiO _{2 according} to any one of (1) to (3), wherein the substrate has a form of a flat plate, a particle, a fiber, or a complex shape.
(5) nanocrystals integrated TiO ₂ has the form of a nanocrystalline integrated TiO ₂ film was deposited on nanocrystalline integrated TiO ₂ particles to the substrate, wherein (1) or nanocrystalline integrated TiO ₂ according to (2) .
(6) A method for producing nanocrystal-integrated TiO ₂ deposited on a substrate or in a solution, and 1) acicular TiO ₂ nano-particles on a substrate or in a solution using a solution reaction system for depositing titanium oxide crystals. Crystals are formed in the liquid phase, 2) At that time, using the nanocrystal growth conditions in a light white solution that is specifically realized in the early stage of the reaction, 3) The produced acicular TiO ₂ nanocrystals are integrated , to synthesize nanocrystals integrated TiO _2, the manufacturing method of the nanocrystalline integrated TiO _2, characterized in that.
(7) reaction temperature, raw material concentration, additives and / or precipitate the acicular TiO ₂ nanocrystals in the liquid phase by adjusting the pH, a method of manufacturing nanocrystalline integrated TiO ₂ according to (6) .
(8) As a solution reaction system, ammonium fluoride titanate, sodium hexafluorotitanium (IV) acid (Na ₂ TiF ₆ ), potassium hexafluorotitanium (IV) acid (K ₂ [TiF ₆ ]), sodium titanate ( Na ₂ Ti ₃ O ₇ ), acetylacetone titanyl (TiO (CH ₃ COCHCOCH ₃ ) ₂ ), titanium (IV) ammonium oxalate (n hydrate) ((NH ₄ ) ₂ [TiO (C ₂ O ₄ ) ₂ ] NH ₂ O), potassium titanium (IV) oxalate (dihydrate) (K ₂ [TiO (C ₂ O ₄ ) ₂ ] · 2H ₂ O), titanium (III) sulfate (n hydrate) [ first] _{(Ti 2 (SO 4) 3} · nH 2 O), or titanium sulfate (IV) (n-hydrate) [second] _{(Ti (SO 4) 2 ·} nH 2 O) by the titanium-containing aqueous solution Used method for producing nanocrystalline integrated TiO ₂ according to (6).
(9) The method for producing nanocrystal-integrated TiO _{2 according} to (6), wherein a reaction system of an aqueous solution reaction, a non-aqueous solution reaction, or a hydrothermal reaction is used as the solution reaction system.
(10) nanocrystals integrated TiO ₂ has the form of a nanocrystalline integrated TiO ₂ film was deposited on nanocrystalline integrated TiO ₂ particles to the substrate, method of manufacturing nanocrystalline integrated TiO ₂ according to (6).
(11) Anatase composed of nanocrystal-integrated TiO ₂ particles or nanocrystal-integrated TiO ₂ film, characterized in that it contains the nanocrystal-integrated TiO _{2 according} to any one of (1) to (5) as a constituent element TiO ₂ based device.

Next, the present invention will be described in detail.
The present invention relates to a nanocrystal integrated TiO ₂ deposited on a substrate or in a solution in a solution reaction system in which a titanium oxide crystal is deposited, and the nanocrystal is composed of a single phase of anatase TiO ₂ and is outward from the particle center. has a needle-like crystals grown along the c axis, even at the tip portion of the needle-like crystals are composed of anatase TiO ₂ single phase, having the structure of anatase TiO ₂ crystal is exposed to the surface, it It is characterized by.

In the present invention, the nano-sized open pores and the surface uneven structure are realized on the surface and inside of the particle, and the nanocrystal integrated TiO ₂ is deposited on the nanocrystal integrated TiO ₂ particles or the substrate. Having a form of TiO ₂ film is a preferred embodiment.

The present invention is also a method for producing nanocrystal-integrated TiO ₂ deposited on a substrate or in a solution, and using a solution reaction system for depositing titanium oxide crystals on the substrate, needles are formed on the substrate or in the solution. the Jo TiO ₂ nanocrystals to form a liquid phase, in this case, using nano crystal growth conditions in a thin white solution specifically realized in the initial reaction, the resulting acicular TiO ₂ nanocrystals are integrated The nanocrystal integrated TiO ₂ is synthesized. Furthermore, the present invention is an anatase TiO ₂ -based device composed of nanocrystal-integrated TiO ₂ particles or nanocrystal-integrated TiO ₂ film, characterized in that it contains the nanocrystal-integrated TiO ₂ as a constituent element. It is.

In the present invention, a nanocrystal integrated TiO ₂ particle or a nanocrystal integrated TiO ₂ particle film is synthesized. The synthesized TiO ₂ particles exhibit a BET specific surface area of 270 m ² / g, or 151 m ² / g. In this process, high temperature heat treatment is not required, and anatase TiO ₂ can be synthesized under low temperature conditions of 50 ° C., so problems such as particle aggregation and surface area reduction associated with high temperature treatment can be assured. It is possible to avoid it.

When the particles of TiO ₂ particles are coated with an amorphous phase or a second phase, the properties of the TiO ₂ particles deteriorate. However, in this process, the amorphous phase and the second phase are not included, and the anatase TiO ₂ single phase is used. Since they can be synthesized, for example, 100% of the particles can function as a photocatalyst or the like with high efficiency.

In the present invention, not only the synthesis of nano TiO ₂ particles but also a nano TiO ₂ particle film can be formed. At that time, high temperature heat treatment for crystallization is not required, and development on various low heat resistant substrates is possible. Reaction starting from the initial reaction of about 30 minutes, by using a nano particle generator and growth conditions, it is possible to realize a synthesis of nano TiO ₂ integrated particles with high efficiency.

In particular, at the initial stage of the reaction within about 30 minutes from the start of the reaction, the solution is colored from white to white. On the other hand, after about 30 minutes, the solution rapidly becomes cloudy due to uniform nucleation of TiO ₂ particles. The change in the solution conditions is very large. For example, by actively utilizing the nanoparticle generation and growth conditions at the initial stage of the reaction, the solution and the particles in the synthesis condition in which the solution and the particles are separated by centrifugation after 30 minutes, Thereafter, the BET specific surface area greatly differs from the particles under the synthesis conditions in which the particles existed in the solution by natural cooling.

In particular, the present invention actively uses nanocrystal formation and growth conditions in a light white solution that is specifically realized in the early stage of the reaction to form needle-like TiO ₂ nanocrystals with a high specific surface area, The most important feature is to synthesize nano-TiO ₂ crystal particles with high efficiency.

Examples of the titanium-containing solution include ammonium hexafluorotitanate (Na ₂ TiF ₆ ) and potassium hexafluorotitanate (IV) (K ₂ [TiF ₆ ], Sodium titanate (Na ₂ Ti ₃ O ₇ ), acetylacetone titanyl (TiO (CH ₃ COCHCOCH ₃ ) ₂ ), titanium oxalate ammonium (IV) ammonium (n hydrate) ((NH ₄ ) ₂ [TiO ( _{C 2 O 4) 2] ·} nH 2 O), titanium oxalate (IV) potassium _{(dihydrate) (K 2 [TiO (C} 2 O 4) 2] · 2H 2 O), titanium (III) sulfate (N hydrate) [first] (Ti ₂ (SO ₄ ) ₃ · nH ₂ O), titanium sulfate (IV) (n hydrate) [second] (Ti (SO ₄ ) ₂ · nH ₂ O ) Etc. Titanium-containing aqueous solution that can be used.

  Further, in the present invention, an aqueous solution reaction system in which titanium oxide crystals are precipitated can be used. However, the present invention is not limited to this, and any non-aqueous solution such as an organic solution can be used as long as it is a reaction system in which titanium oxide crystals precipitate. A reaction system can also be used. Moreover, a hydrothermal reaction etc. can also be used if it is a reaction system which a titanium oxide crystal precipitates.

Anatase TiO ₂ crystals can also be precipitated by changing temperature, raw material concentration, and / or pH without adding boric acid. The temperature can also be appropriately adjusted in the range from the freezing point of the aqueous solution to the boiling point (approximately 0 to 99 ° C.) according to the raw material concentration, additives, and / or pH.

In producing the TiO ₂ film, various substrates such as silicon, glass, metal, ceramics, and polymer can be used. Moreover, as a board | substrate, the board | substrate of appropriate forms, such as a particle | grain base material, a fiber base material, and a complex shape base material other than a flat substrate, can be used.

In the present invention, anatase TiO ₂ particles having a diameter of 100 to ₂₀₀ nm can be synthesized using an aqueous solution at a low temperature of 50 ° C. This particle is an aggregate of nano TiO ₂ crystals, and the surface is covered with a nano-sized uneven structure. The nano TiO ₂ crystal grows anisotropically along the c-axis direction and forms a long crystal. Therefore, from the XRD analysis of the powder, a strong diffraction line from the (004) plane is observed, indicating a high c-axis orientation. The TiO ₂ particles exhibit a high BET specific surface area of 270 m ² / g in nitrogen adsorption measurement.

BJH analysis and DFT / Monte-Carlo analysis of adsorption isotherms showed the presence of about 3 nm mesopores. In this process, nano-self-organized TiO ₂ particles having a high surface area and a nano-sized concavo-convex structure were synthesized by skillfully utilizing nano-TiO ₂ self-organization and crystal growth. In addition, it was found that in this process, the synthesis of nanocrystalline self-organized TiO ₂ particles having a high surface area and a nano-sized uneven structure can be realized by skillfully utilizing nano-TiO ₂ self-organization and crystal growth. .

The application fields of the nanocrystal integrated TiO ₂ (nanoTiO ₂ crystal aggregate) of the present invention include, for example, photocatalysts, cosmetics, dye-sensitized solar cells, molecular sensors, gas sensors, solution sensors, antifouling coatings, and antifogging. Examples include coatings and superhydrophilic surface coatings.

As described above in detail, according to the present invention, it has been realized that anatase TiO ₂ particles having a diameter of 100 to ₂₀₀ nm can be synthesized without going through a high-temperature heat treatment step. This particle is an aggregate of nano TiO ₂ crystals, the surface is covered with nano-sized uneven structure, nano TiO ₂ crystals grow anisotropically along the c-axis direction, forming a long crystal From the XRD analysis of the powder, a strong diffraction line from the (004) plane is observed and a high c-axis orientation is shown. In the nitrogen adsorption measurement, a high BET specific surface area of 151-270 m ² / g is shown. BJH analysis of the line and DFT / Monte-Carlo analysis indicate the presence of mesopores of about 3 nm, the TiO ₂ particles show the XRD pattern of FIG. 1, the particle diameter from TEM observation is about 100-200 nm And having a positive zeta potential at pH 3.1.

The present invention has the following effects.
(1) Nanocrystal integrated TiO ₂ particles or nanocrystal integrated TiO ₂ films can be synthesized.
(2) Nanocrystal-integrated TiO ₂ particles having a high specific surface area of 151 to 270 m ² / g, which is not a case in conventional materials, can be synthesized with a BET specific surface area.
(3) The particles of the present invention can be obtained as a colloidal solution dispersed in a solution such as water or as a dry powder.
(4) A nanocrystal integrated TiO ₂ particle film can be formed on an arbitrary substrate.
(5) A TiO ₂ particle film can be formed on various base materials or substrates regardless of the substance, shape, size, and the like.
(6) In this process, since no organic substance is added, contamination of impurities can be avoided reliably.
(7) The nanocrystal integrated TiO ₂ particles and the particle film can be synthesized under a low temperature condition of about 50 ° C.
(8) Various anatase TiO ₂ device products composed of the nanocrystal integrated TiO ₂ can be provided.

  EXAMPLES Next, although this invention is demonstrated concretely based on an Example, this invention is not limited at all by the following Examples.

(1) Synthesis of nanocrystal integrated TiO ₂ Ammonium fluoride titanate (12.372 g) and boric acid (11.1852 g) were dissolved in distilled water (600 ml) at 50 ° C., respectively. The aqueous boric acid solution was added to the aqueous ammonium fluoride titanate solution. The concentrations of ammonium fluoride titanate and boric acid in this mixed solution are 0.15 M and 0.05 M, respectively.

  This mixed aqueous solution was kept at 50 ° C. without stirring for 30 minutes. Thereafter, the solution was centrifuged at 4000 rpm for 10 minutes. Preparations before centrifugation, centrifugation at 4000 rpm, deceleration from 4000 rpm to 0 rpm, and preparation for supernatant removal were 4 minutes, 10 minutes, 10 minutes, and 8 minutes, respectively.

Therefore, the TiO ₂ particles were in contact with the aqueous solution that gradually decreased in temperature after being held at 50 ° C. for 30 minutes for 32 minutes. After removing the supernatant, the particles were dried at 60 ° C. for 12 hours to obtain TiO ₂ particles.

(2) Measurement of characteristics of synthesized TiO ₂ particles 1) Measuring method The crystal structure of the particles was measured with an X-ray diffractometer (XRD; RINT-2100V, Rigaku) (using CuKα rays, 40 kV, 30 mA).

  The morphology of the particles was measured using a transmission electron microscope (TEM; JEM2010, 200 kV, JEOL). The zeta potential and particle size distribution were measured using a zeta potential / particle size measurement system (ELS-Z2, Otsuka Electronics Co., Ltd.) equipped with an automatic pH titrator.

  As a pretreatment for measurement, 0.01 g of a powder sample was dispersed in 100 ml of distilled water, and sonication was performed for 30 minutes. The pH of the colloidal solution was adjusted using HCl (0.1M) or NaOH (0.1M).

  Nitrogen adsorption measurement was performed using 0.137 g of the sample, and after heating the sample at 110 ° C. under reduced pressure (10-2 mmHg or less) for 6 hours, using Autosorb-1 (Quantachrome Instruments). The specific surface area was calculated by the BET (Brunauer-Emmett-Teller) method using an adsorption isotherm.

  The pore distribution was measured by the BJH (Barrett-Joyner-Halenda) method using an adsorption isotherm. This is because a pseudo peak was observed in the BJH analysis using the desorption isotherm.

Furthermore, the pore distribution was measured by the DFT / Monte-Carlo method (N ₂ at 77K on silica (cylinder./sphere, pore, NLDFT ads. Model) method using an adsorption isotherm.

2) Measurement results From XRD measurement of the powder after nitrogen adsorption, 2θ = 25.1, 37.9, 47.6, 54.2, 62.4, 69.3, 75.1, 82.5 and 94 A diffraction line was observed at 0.0 °. These were assigned to the 101,004,200,105 + 211,204,116 + 220,215,303 + 224 + 312 and 305 + 321 diffraction lines of anatase TiO ₂ (JCPSD No. 21-1272, ICSD No. 9852). FIG. 1 shows an XRD pattern of TiO ₂ particles.

As seen in JCPDS data (No. 21-1272), in the randomly oriented particles, the 004 diffraction line intensity is usually about 0.2 times the 101 diffraction line intensity. However, the 004 diffraction intensity of the synthesized TiO ₂ particles was 0.36 times the 101 diffraction intensity. The integrated intensity of the 004 diffraction line was 0.18 times the integrated intensity of the 101 diffraction line.

This indicates that the TiO ₂ particles have c-axis orientation. In the XRD measurement, the particles on the glass are not aligned and aligned. Therefore, it is considered that the TiO ₂ particles are anisotropically grown preferentially in the c-axis direction and have an anisotropic form.

  It is considered that the crystal has a larger number of c-plane laminates such as the (001) plane than the (101) plane laminate. Therefore, it is considered that the diffraction line from the (004) plane was observed stronger than the diffraction line from the (101) plane. From the half widths of the 101 diffraction line and the 004 diffraction line, the crystallite sizes in the direction perpendicular to the (101) and (004) planes were estimated to be 3.9 nm and 6.3 nm, respectively.

Anisotropic growth in the c-axis direction was also shown by the difference in crystallite size for each orientation. TEM observation showed that the TiO ₂ particles were an aggregate of nano-sized TiO ₂ crystals. FIG. 2 shows a TEM image (a) of the TiO ₂ particles, an enlarged image (b) thereof, an FFT image (inset), and an enlarged image (c) of (a). The diameter of the particles was about 100-200 nm. Since porous particles are constituted by accumulation of nano-sized acicular crystals, the particle surface is covered with nano-sized uneven structures, and nano-sized open pores exist inside the particles.

The upper right region of the particle is shown in FIG. The nanocrystals had a 5-10 nm needle shape. From the FFT image (Fourier transform image) of the inset, 101 and 004 diffraction lines of anatase TiO ₂ were observed, indicating that the nanocrystal was a single phase of anatase TiO ₂ . It should be noted that the diffraction line intensity from the (004) plane in the upper right part and the lower left part in the FFT image is high.

In FIG. 2b, acicular crystals (in the direction from the particle center to the upper right part) whose longitudinal direction is directed to the upper right part are observed. These suggest that the acicular crystal grew along the c-axis and thus increased the diffraction intensity from the (004) plane. A lattice image of anatase TiO ₂ was also observed from the nano needle crystals (FIG. 2c).

These needle-like crystals did not contain an amorphous phase or other phases, and were composed of anatase TiO ₂ single phase. Even at the tip of the needle-like crystal, the anatase TiO ₂ crystal was not covered with the amorphous phase or the other phase. The fact that the surface is not covered with other components and the anatase TiO ₂ crystals are exposed is an important factor in catalysts and many other applications.

In this process, an aggregate of nano-needle crystals was realized by effectively utilizing nanocrystallization of TiO ₂ . In addition, by realizing the integration of nanocrystals, nano-sized open pores and surface uneven structures were realized on the surface and inside of the particles.

In this example, the zeta potential and particle size distribution of the TiO ₂ particles synthesized in Example 1 were evaluated. The dried particles after nitrogen adsorption were dispersed in water, and the zeta potential and particle size distribution of the particles were measured by the measurement method described in Example 1. The zeta potential and particle size distribution were measured at 25 ° C. and integrated 5 times or 70 times, respectively. As a result, the particles showed a positive zeta potential of 30.2 mV at pH 3.1.

The zeta potential is 5.0 mV, −0.6 mV, −11.3 mV, and −36 at pH 5.0, 7.0, 9.0, and 11.1, respectively, as the pH increases. The isoelectric point was estimated to be pH 6.7. This was a slightly higher value than the literature value of anatase TiO ₂ (pH 2.7-6.0) 28 [literature: Furlong, D. et al. N. Parfitt, G .; D. , J .; Colloid Interface Sci. 1978, 65, (3), 548-554].

  The zeta potential is very sensitive to the state of the particle surface, adsorbed ions, the type and concentration of ions in the solution, and the like. The difference in zeta potential is thought to be caused by the interaction of particles and ions in solution. The average particle size at pH 3.1 was estimated to be about 550 nm with a standard deviation of 220 nm.

  This was a value larger than the size obtained by TEM observation. This is presumably because the particles before the particle size distribution measurement were in a completely dry state, so that they were loosely aggregated in pH 3 water. The particle size increased with increasing pH, and showed a maximum value of 4300-5500 nm in the vicinity of the isoelectric point.

  In the vicinity of the isoelectric point, there is very little repulsive force between the particles, so it is considered that the particles were strongly aggregated. In this process, particles are generated in a solution having a pH of 3.8. This solution condition is considered to be a suitable condition for causing repulsive force between the particles to crystallize the particles without strong aggregation.

In this example, nitrogen adsorption of the particles synthesized in Example 1 was evaluated. The TiO ₂ particles showed an IV type nitrogen adsorption / desorption isotherm (FIG. 3a). In the range of relative pressure (P / P ₀ ) from 0.4 to 0.7, the desorption isotherm behaved differently from the adsorption isotherm. FIG. 3 shows adsorption / desorption isotherm of TiO ₂ particles (Adsorption + Deposition Isothermal plot) (a), evaluation results of BET specific surface area of TiO ₂ particles (BET plot) (b), pore size distribution calculated by BJH method (BJH Adsorption) Dv (logd)) (c), adsorption / desorption isotherm of TiO ₂ particles, and fitting curve by DFT / Monte-Carlo method (DFT / Monte-Carlo Fitting) (d), and calculation by DFT / Monte-Carlo method The pore volume distribution (Pore Volume Distribution) (e) is shown.

These results indicate that the particles have mesopores. The BET specific surface area was estimated to be 270 m ² / g (FIG. 3b). This was a very large value compared with the conventional product TiO ₂ nanoparticles [Document: Wahi, R .; K. Liu, Y .; P. Falkner, J .; C. Colvin, V .; L. , Journal of Colloid and Interface Science 2006, 302, (2), 530-536].

As the TiO ₂ nanoparticles of the conventional product, as shown in the above document, AEROXIDE P 25 (BET 50 m ² / g, 21 nm in diameter, anatase 80% + rutile 20%, Degussa), AEROXIDE P 90 (BET 90-100 m ² / g, 14 nm in diameter, anatase 90% + rutile 10%, Degussa), MT-01 (BET 60 m ² / g, 10 nm in diameter, rutile, Tayca Corp.) and Altair TiNano ET ^{2 B} / E g, 30-50 nm in diameter, Altair Nanotechnologies Inc.).

Even if the particle size is 100 nm or less, it is not possible to obtain a high BET specific surface area for particles having a smooth surface. Since the TiO ₂ particles synthesized by this process have a specific form of nanocrystal aggregates, it is considered that a high BET specific surface area could be realized.

The total pore volume (V) and the average pore diameter (4 V / A) are BET surface area (A) 270 m ² / g from pores having a diameter of 230 nm or less with a relative pressure P / Po = 0.99. Estimated to be 0.43 cc / g and 6.4 nm, respectively. However, since the adsorption amount increases rapidly at a high relative pressure, the adsorption amount at a high relative pressure includes a large error.

Therefore, from pores having a relative pressure P / Po = 0.80 and a diameter of 11 nm or less, the total pore volume (V) and average pore diameter (4 V / A) are 0.21 cc / g and 3.1 nm. Estimated. These numerical values can be compared with TiO ₂ particles having the same form with high accuracy.

When the pore size distribution was evaluated by the BJH method using the adsorption isotherm, it had a peak at about 2.8 nm (FIG. 3c). This indicates that the TiO ₂ particles have about 2.8 nm mesopores surrounded by nanocrystals. The pore size distribution suggested the presence of micropores of 1.0 nm or less.

  After evaluating adsorption characteristics at a low relative pressure using a small amount of sample, the pore size distribution was evaluated using the DFT / Monte-Carlo method. The calculation model showed a high degree of agreement with the adsorption isotherm (FIG. 3d). The pore size distribution has a peak at about 3.6 nm, indicating the presence of 3.6 nm mesopores (FIG. 3e).

  The mesopore size calculated by the DFT / Monte-Carlo method was slightly larger than the mesopore size calculated by the BJH method. This is generally considered to be due to the fact that the pore diameter calculated by the BJH method is estimated to be small [Reference: 1) Kruk, M .; Jaroniec, M .; Chemistry of Materials 2001, 13, (10), 3169-3183, 2) Ravikovitch, P .; I. Odomhnill, S .; C. Neimark, A .; V. Schuth, F .; Unger, K .; K. Langmuir 1995, 11, (12), 4765-4772, 3) Lastoskie, C .; Gubins, K .; E. Quirke, N .; , Journal of Physical Chemistry 1993, 97, (18), 4786-4796].

  Further, the analysis by the DFT / Monte-Carlo method also showed the presence of micropores of about 1.4 nm or less. Using 0.0143 g of particles, the adsorption isotherm was measured in the range of low relative pressure P / Po = 3.9 × 10 −6 to 1.0 relative pressure, and the DFT / Monte-Carlo method was used. The pore size was evaluated. The result showed the presence of 0.96 nm micropores in addition to ~ 3.6 nm mesopores.

In this example, TiO ₂ particles were synthesized under the following conditions and method. After mixing the 50 ° C. ammonium fluoride titanate aqueous solution and the boric acid aqueous solution, this was held at 50 ° C. for 30 minutes. Next, it was allowed to cool naturally to 25 ° C. and held for 48 hours to allow the particles to settle naturally, and then the supernatant was removed.

Further, 50 ° C. water was added thereto and stirred, and then kept for 24 hours to allow the particles to settle naturally, and then the supernatant was removed. Subsequently, similarly, dispersion with water at 50 ° C., holding for 24 hours, and removal of the supernatant were performed twice. Thereafter, it was air-dried at 60 ° C. for 24 hours to obtain a powder sample. This powder sample exhibited a BET specific surface area of 151 m ² / g.

In this example, nano acicular anatase TiO ₂ crystal integrated particles and anatase TiO ₂ crystal film were prepared. Ammonium fluoride titanate ([NH ₄ ] ₂ TiF ₆ ) (2.00096 g) and boric acid (1.86422 g) were dissolved in 100 mL of distilled water at 50 ° C., respectively. Both aqueous solutions were mixed, and an FTO substrate (FTO, SnO ₂ : F, Asahi Glass Co., Ltd., 9.3-9.7Ω / □, 26 × 50 × 1.1 mm) was immersed in this. Then, it kept at 50 degreeC for predetermined time using water bath.

  The concentrations in the mixed solution of ammonium fluorotitanate and boric acid are 0.15 M and 0.05 M, respectively. Under this solution condition, the pH is about 3.9. The solution began to whiten about 10 minutes after the start of the reaction. Next, the FTO substrate was immersed in the solution, and then the substrate was washed with distilled water and allowed to air dry.

In the optical photograph of the anatase TiO ₂ crystal film formed on the FTO substrate, the TiO ₂ thin film formation site was colored slightly white. This indicates the absence of colored by-products. The white color is uniform over the entire surface of the TiO ₂ film, indicating the uniformity of the film thickness.

In sonicated for 30 minutes in acetone with respect to the TiO ₂ film, peeling of the formed TiO ₂ film was observed. When XRD observation of the TiO ₂ film formed on the FTO substrate was performed, it was difficult to evaluate the diffraction line from TiO ₂ due to the strong XRD peak derived from tin oxide, so it was formed on the glass substrate without FTO coating. The XRD pattern of the TiO ₂ film was evaluated.

FIG. 4 shows an X-ray diffraction pattern of the anatase TiO ₂ crystal film formed on the glass substrate. Weak diffraction lines are observed at 2θ = 25.3, 37.7, 48.0, 53.9, 55.1, and 62.7 °, and 101, anatase TiO ₂ (ICSD No. 9852), 004, 200, 105, 211, and 204 diffraction lines.

  The intensity of the 004 diffraction line is very strong, indicating a high c-axis orientation. The integrated intensity ratio (integrated area ratio) of the 004 diffraction line and the 101 diffraction line was 2.6 times, and the intensity height ratio was 2.2 times. The crystallite size in the direction perpendicular to the (004) plane was estimated to be 17 nm using the Scherrer equation from the half-width of the diffraction line. A broad peak derived from the glass substrate was also observed at 2θ = 25 °. The film thickness when immersed for 2 hours was about 260 nm.

The TiO ₂ film thickness increased with increasing immersion time, and the crack size increased with increasing immersion time. Since a thick TiO ₂ film has high strength, it is considered that stress accumulation occurs, which suppresses the generation of small cracks and promotes the growth of large cracks. The shape of the grain boundary changed with the growth of the particle film.

The acicular crystals on the particle surface grew with increasing immersion time. The TiO ₂ film thickness accompanying the change in the immersion time increased rapidly at the initial stage of immersion, and the growth rate gradually changed as the immersion time increased.

As a result of evaluating the XRD pattern of the anatase TiO ₂ crystal powder (TiO ₂ crystal precipitation powder) synthesized in the solution, 101 diffraction lines (around 2θ = 25 °) and 004 diffraction were observed for TiO ₂ in ICSD data (No. 9852). The relative intensity ratio (height) of the line (around 2θ = 38 °) was 1: 0.1915, whereas in the synthesized anatase TiO ₂ crystal particles, it was 1: 0.6647. The synthesized anatase TiO ₂ crystal particles have strong 004 diffraction intensity and are shown to have high c-axis orientation.

To summarize the precipitation reaction, as shown by the whitening of the solution at the initial stage of the reaction, first, the formation and growth of anatase TiO ₂ particles occurred, and TiO ₂ particles were generated. TiO ₂ particles grow further, increase in size, and settle slowly. Those particles also adhere to the substrate. Therefore, the growth of the fast TiO ₂ film is caused. Heterogeneous nucleation on the substrate also proceeds at the same time. Since the ion concentration in the solution is high at the initial stage of the reaction, the crystal growth rate of TiO ₂ is high, and the increase in the TiO ₂ film thickness is promoted.

Ion concentration in the solution, in order to gradually decrease the growth of the product and the TiO ₂ film of TiO ₂ particles, an increase in TiO ₂ thickness, will gradually become loose. As the immersion time increases, the amount of particles generated by uniform nucleation decreases, and it is considered that the crystal growth of the TiO ₂ film by ion incorporation becomes dominant. In the observation of the surface of the TiO ₂ film, it was observed that the unevenness due to the particles was smoothed and the grain boundary became unclear as the TiO ₂ film was grown.

In this example, on the FTO substrate surface, a surface patterned into a superhydrophilic region and a hydrophobic region is formed, and by using the superhydrophilic / hydrophobic region patterned surface, on the substrate, to form the anatase crystal TiO ₂ pattern.

An FTO substrate (FTO, SnO ₂ : F, Asahi Glass Co., Ltd., 9.3-9.7Ω / □, 26 × 50 × 1.1 mm) was irradiated with ultraviolet rays (UV) for 10 minutes. For UV irradiation, a low-pressure mercury lamp (PL16-110) manufactured by Sen Special Light Source was used. The main wavelengths of light in this light source are 184.9 nm and 253.7 nm.

  The initial FTO surface is a hydrophobic surface with a water contact angle of 96 °, whereas with increasing UV irradiation time, the contact angle is 70 ° (0.5 minutes), 54 ° (1 minute). , 30 ° (2 minutes), 14 ° (3 minutes), 5 ° (4 minutes) and 0 ° (5 minutes). After 5 minutes, the contact angle is over 0 ° below the measurement limit. It showed hydrophilicity.

In order to modify the surface of the FTO group, a photomask (manufactured by Toppan Printing, test chart No. 1-N type, (Test-chart-No. 1-N type, quartz substrat, 1.524 mm thickness, guarded line width). TiO ₂ pattern was formed on the FTO substrate by UV irradiation through 2 μm ± 0.5 μm, Toppan Printing Co., Ltd.)).

Ammonium fluoride titanate ([NH ₄ ] ₂ TiF ₆ ) (2.00096 g) and boric acid (1.86422 g) were each dissolved in 100 mL of distilled water at 50 ° C. Both aqueous solutions were mixed, and an FTO substrate (FTO substrate subjected to UV irradiation treatment through a photomask) was immersed therein, and then kept at 50 ° C. for a predetermined time using a water bath.

  The concentrations in the mixed solution of ammonium fluorotitanate and boric acid were 0.15 M and 0.05 M, respectively. Under this solution condition, the pH was about 3.9. The solution began to whiten about 10 minutes after the start of the reaction. Thereafter, the particles generated in the solution gradually settled.

After immersion, the substrate was washed with distilled water and allowed to air dry. The FTO before immersion exhibited a bluish green color, whereas the superhydrophilic region after immersion exhibited a yellowish green color. Moreover, the hydrophobic area | region after immersion was blue-green similarly to before immersion. This is presumably because the wavelength of the diffracted light changed because a transparent TiO ₂ film was formed on the FTO. The super hydrophilic region was black and the hydrophobic region was white.

  The standard deviation of the line edge roughness is estimated to be about 2.8 μm, and from this, the roughness can be estimated to be about 5% (2.8 / 55). This was comparable to the current reference value of 5% for forming electronic devices. Since the minimum line width depends on the minimum line width of the photomask and the irradiation light wavelength, it is considered that the minimum line width can be improved to at least 1 μm or less by using a high-resolution photomask.

As a result of observing the TiO ₂ deposited in the UV irradiation FTO region and the FTO surface in the UV non-irradiation region with an SEM photograph, the FTO layer serving as a substrate is a particle film having a large roughness and an angular particle having a diameter of about 100 to 500 nm Consisted of. Further, TiO ₂ was hardly observed from the hydrophobic region.

On the other hand, the TiO ₂ micropattern region formed along the superhydrophilic region was covered with a nanocrystal aggregate of 10-30 nm. This nanocrystal is considered to be an anatase TiO ₂ crystal grown anisotropically. In addition to the nano-sized irregularities composed of nanocrystals, the TiO ₂ film also had large irregularities with a diameter of about 100-500 nm.

This is presumably because the nano-TiO ₂ layer was thinly formed on the FTO layer composed of angular particles, and thus the surface of the TiO ₂ layer had a large uneven shape of the FTO substrate. Due to these effects, the TiO ₂ film had a unique hybrid hierarchical concavo-convex structure having nano-sized concavo-convex composed of small nanocrystals and large concavo-convex derived from the surface shape of FTO.

As a result of observing a cross section of the TiO ₂ film formed on the FTO with an SEM photograph, a polycrystalline FTO layer having large surface irregularities was formed on the glass substrate with a thickness of about 900 nm. The roughness of the FTO layer was about 100-200 nm. Nano TiO ₂ crystals were observed from the superhydrophilic FTO surface.

On the other hand, TiO ₂ was not observed from the hydrophobic FTO surface. The superhydrophilic FTO surfaces were covered with an array of nano TiO ₂ crystals, which had a long shape with a diameter of about 20 nm and a length of about 150 nm. These observation results are consistent with the evaluation in XRD and TEM.

The nano TiO ₂ crystal preferentially grows anisotropically in the c-axis direction, and as a result, it is considered that the 004 diffraction intensity is stronger than the 101 diffraction line intensity in electron diffraction during XRD or TEM observation. It is done.

As a result of anisotropic growth in the c-axis direction, the nanoTiO ₂ crystal is considered to have grown into a shape having a high aspect ratio (length 150 nm / diameter 20 nm). In addition, as observed in the SEM image, the crystal grown anisotropically in the c-axis direction grows so that the c-axis is perpendicular to the FTO substrate. This is a strong 004 in XRD and electron beam diffraction. It is considered that the diffraction intensity (c-axis orientation) was brought about.

When XRD observation of the TiO ₂ film formed on the FTO substrate was performed, it was difficult to evaluate the diffraction line from TiO ₂ due to the strong XRD peak derived from tin oxide, so it was formed on the glass substrate without FTO coating. FIG. 5 shows an XRD pattern of the obtained TiO ₂ film. The substrate was immersed immediately after preparation of the mixed solution.

Weak diffraction lines are observed at 2θ = 25.3, 37.7, 48.0, 53.9, 55.1, and 62.7 °, and 101,004 of anatase TiO ₂ (ICSD No. 9852). , 200, 105, 211, and 204 diffraction lines. The intensity of the 004 diffraction line is very strong, indicating a high c-axis orientation. The integrated intensity ratio (integrated area ratio) of the 004 diffraction line and the 101 diffraction line was 2.6 times, and the intensity height ratio was 2.2 times.

The crystallite size in the direction perpendicular to the (004) plane was estimated to be 17 nm using the Scherrer equation from the half-width of the diffraction line. A broad peak derived from the glass substrate was also observed at 2θ = 25 °. Immediately after preparation of the mixed solution, the substrate was immersed to form a TiO ₂ film on the FTO substrate.

As described above in detail, the present invention relates to nanocrystal-integrated TiO ₂ and a method for producing the same. According to the present invention, nanocrystal-integrated TiO ₂ particles having a BET specific surface area of 151 to 270 m ² / g A nanocrystal integrated TiO ₂ film can be synthesized. These can be obtained as a colloidal solution dispersed in water or as a dry powder, and a TiO ₂ particle film can be formed on a substrate. A TiO ₂ particle film can be formed on the material and the substrate. In this process, since organic substances are not added, mixing of impurities can be avoided, and TiO ₂ particles and a particle film can be synthesized at a low temperature of 50 ° C. INDUSTRIAL APPLICABILITY The present invention is useful as a nanocrystal integrated TiO ₂ particle or nanocrystal integrated TiO ₂ film that can be suitably used for various TiO ₂ device products and their device products.

It shows the XRD pattern of the TiO ₂ particles. A TEM image (a) of TiO ₂ particles is shown. (B) is an enlarged image of (a) and (inset) FFT image. (C) is an enlarged image of (a). The adsorption / desorption isotherm (a) of TiO ₂ particles is shown. (B) is a BET specific surface area evaluation of TiO ₂ particles. (C) is the pore size distribution calculated by the BJH method. (D) is an adsorption / desorption isotherm of TiO ₂ particles and a fitting curve by the DFT / Monte-Carlo method. (D) is a pore size distribution calculated by the DFT / Monte-Carlo method. The X-ray diffraction pattern of anatase TiO ₂ crystal film formed on a glass substrate. ₂ shows an X-ray diffraction pattern of a TiO ₂ crystal film formed on a substrate.

Claims (11)

Nanocrystal-integrated TiO ₂ deposited on a substrate or in a solution in a solution reaction system in which titanium oxide crystals are deposited. 1) The nanocrystal is composed of a single phase of anatase TiO ₂ and 2) outward from the particle center. It has a needle-like crystal grown along the c-axis, 3) the tip portion of the needle-like crystal is also composed of a single phase of anatase TiO ₂ , and 4) a structure in which the anatase TiO ₂ crystal is exposed on the surface. Nanocrystal integrated TiO ₂ characterized by having. _2. The nanocrystal-integrated TiO _{2 according} to claim 1, wherein nano-sized open pores and a surface uneven structure are realized on the surface and inside of the particle. The nanocrystal integrated TiO _{2 according} to claim 1 or 2, wherein the substrate is a glass, silicon, metal, ceramic, or polymer substrate. The nanocrystal integrated TiO _{2 according} to any one of claims 1 to 3, wherein the substrate has a form of a flat plate, a particle, a fiber, or a complex shape. Nanocrystalline integrated TiO ₂ has the form of a nanocrystalline integrated TiO ₂ film was deposited on nanocrystalline integrated TiO ₂ particles to the substrate, according to claim 1 or nanocrystalline integrated _TiO 2 according to 2. A method for producing nanocrystal-integrated TiO ₂ deposited on a substrate or in a solution, wherein 1) liquid needle-like TiO ₂ nanocrystals are deposited on a substrate or in a solution using a solution reaction system for depositing titanium oxide crystals. 2) Utilizing nanocrystal growth conditions in a light white solution that is specifically realized at the initial stage of the reaction, 3) integrating the produced needle-like TiO ₂ nanocrystals to form nanocrystals A method for producing nanocrystal-integrated TiO _2, which comprises synthesizing integrated TiO ₂ . Reaction temperature, raw material concentration, is deposited in the additive and / or liquid phase acicular TiO ₂ nanocrystals by adjusting the pH, the production method of the nanocrystalline integrated TiO ₂ according to claim 6. As solution reaction systems, ammonium fluoride titanate, sodium hexafluorotitanium (IV) acid (Na ₂ TiF ₆ ), potassium hexafluorotitanium (IV) acid (K ₂ [TiF ₆ ]), sodium titanate (Na ₂ Ti) ₃ O ₇ ), acetylacetone titanyl (TiO (CH ₃ COCHCOCH ₃ ) ₂ ), titanium (IV) ammonium oxalate (n hydrate) ((NH ₄ ) ₂ [TiO (C ₂ O ₄ ) ₂ ] · nH ₂ O), potassium titanium (IV) oxalate (dihydrate) (K ₂ [TiO (C ₂ O ₄ ) ₂ ] · 2H ₂ O), titanium (III) sulfate (n hydrate) [first] _{(Ti 2 (SO 4) 3} · nH 2 O), or a titanium-containing aqueous solution by titanium sulfate (IV) (n-hydrate) [second] _{(Ti (SO 4) 2 ·} nH 2 O) The method of nanocrystalline integrated TiO ₂ according to claim 6. The method for producing nanocrystal-integrated TiO _{2 according} to claim 6, wherein a reaction system of an aqueous solution reaction, a non-aqueous solution reaction, or a hydrothermal reaction is used as the solution reaction system. Nanocrystalline integrated TiO ₂ has the form of a nanocrystalline integrated TiO ₂ film was deposited on nanocrystalline integrated TiO ₂ particles to the substrate, method of manufacturing nanocrystalline integrated TiO ₂ according to claim 6. An anatase TiO ₂ -based device composed of nanocrystal-integrated TiO ₂ particles or nanocrystal-integrated TiO ₂ film, comprising the nanocrystal-integrated TiO _{2 according} to any one of claims 1 to 5 as a constituent element.