JP2003270671A - Electrochromic device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electrochromic device which facilitates full color display, has excellent memory characteristic and by which response speed, color developing efficiency and repetitive durability are greatly improved. <P>SOLUTION: In the electrochromic device, one structural unit is constituted by arranging a pair of transparent electrodes on at least one surface of which a semiconductor nano porous layer is formed, so that the semiconductor nano porous layers are disposed to face each other and holding an electrolyte layer containing an electrochromic dyestuff therebetween. Another structural unit is constituted by arranging a pair of transparent electrodes on at least one surface of which the semiconductor nano porous layer where the electrochromic dyestuff is deposited, is formed so that the semiconductor nano porous layers are disposed to face each other and holding the electrolyte layer therebetween. The electrochromic device is constituted by laminating two structural units plural times. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electrochromic device, and more particularly, it relates to an electrochromic device which can be easily formed into a full color image, has an excellent memory property, and has a significantly improved response speed and repeated durability.

[0002]

2. Description of the Related Art Electrochromic (hereinafter abbreviated as "EC") devices, such as EC display devices, do not require a polarizing plate or the like, and therefore have no light-receiving type and are excellent in visibility and are electrochemically oxidized. The structure is simple and easy to increase in size because at least an electrolyte containing the EC material that reversibly develops or discolors by a reduction reaction and a pair of electrodes are provided. Color tone can be obtained, the display state can be stopped just by blocking the movement of electrons and maintaining the redox state, so that it has excellent memory properties, and it does not require power to maintain the display state, so power consumption is low, It has been applied in various fields because of its various advantages.

For example, an all-solid-state EC in which a transparent electrode layer (cathode), a tungsten trioxide thin film layer (EC layer), an insulating layer such as silicon dioxide, and an electrode layer (anode) are sequentially laminated on a glass substrate. A device is disclosed in Japanese Examined Patent Publication No. 52-46098. When a voltage (coloring voltage) is applied to this EC element, the tungsten trioxide (WO ₃ ) thin film layer is colored blue. After that, when a voltage (decoloring voltage) having a reverse polarity is applied to this EC element, the blue color of the tungsten trioxide thin film layer disappears and it returns to colorless. The mechanism of this color fading has not been clarified in detail, but it is said that a small amount of water contained in the WO ₃ thin film layer and the insulating layer (ion conductive layer) controls the color fading of the WO ₃ thin film layer. To be understood.

Recently, for example, JP-A-9-120088, JP-A-7-152050, and JP-A-6-24.
2474, etc., the EC material is vapor-deposited on a pair of electrodes, and a supporting salt and a solvent are enclosed between the electrodes, or an EC display device between the pair of electrodes. Various EC display devices such as an EC display device in which a supporting salt and a solvent are enclosed have been proposed.

However, in these EC display devices, there is a serious problem that it is difficult to increase the response speed because the movement of the substance (ion) is involved in coloring and decoloring. Especially, in the case of the latter EC display device. However, there is a problem that bleeding occurs due to the diffusion of the coloring substance, and it is difficult to display a high-definition image. Therefore, for example, Japanese Patent Laid-Open No. 2000-
In Japanese Patent Laid-Open No. 19567, it is proposed to use a polymer solid electrolyte in the latter EC display device, but there is a problem that sufficient ionic conductivity is not obtained even by heating and the like and the response is poor.

Therefore, it is easy to realize full color,
It is the current situation that no EC device having excellent memory property and greatly improved response speed, color development efficiency and repeated durability has been provided.

[0007]

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above problems in the prior art and to solve the following problems. That is, an object of the present invention is to provide an EC device which has a simple structure, is easy to manufacture, is easy to realize full color, has excellent memory property, and has significantly improved response speed, coloring efficiency, and repetitive durability. And

[0008]

Means for solving the problems Means for solving the above problems are as follows. That is, <1> electrochemical oxidation reaction and reduction reaction are performed while a pair of transparent electrodes having a semiconductor nanoporous layer formed on at least one surface thereof are arranged so that the semiconductor nanoporous layers face each other. An electrochromic device comprising a plurality of laminated structural units sandwiching an electrolyte layer containing an electrochromic dye that reversibly develops or erases color by at least one of the above. <2> A pair of transparent electrodes having a semiconductor nanoporous layer carrying an electrochromic dye capable of reversibly developing or decoloring by at least one of an electrochemical oxidation reaction and a reduction reaction formed on at least one surface thereof, The electrochromic device is characterized in that a plurality of structural units each having an electrolyte layer sandwiched between the semiconductor nanoporous layers are arranged so as to face each other, and are laminated. <3> The electrochromic device according to <1> or <2>, in which 2 to 4 structural units are stacked. <4> The electrochromic device according to <2> or <3>, in which a different electrochromic dye is supported for each structural unit. <5> The electrochromic device according to any one of <1> to <4>, wherein at least one of the semiconductor nanoporous layers has a multi-layer structure. <6> The electrochromic device according to <5>, wherein both semiconductor nanoporous layers have a multilayer structure. <7> The electrochromic device according to <5> or <6>, in which semiconductor nanoporous layers are laminated by low temperature firing at 150 to 200 ° C. <8> The electrochromic dye different for each layer of the semiconductor nanoporous layer having a multi-layered structure is <5.
The electrochromic device according to any one of <> to <7>. <9> The electrochromic device according to any one of <1> to <8>, further including a charge transfer agent in the electrolyte layer. <10> The electrochromic device according to any one of <2> to <9>, in which the charge transfer agent is carried on the semiconductor nanoporous layer. <11> Any one of the above <1> to <10>, wherein the semiconductor fine particles contained in the semiconductor nanoporous layer are selected from a single semiconductor, an oxide semiconductor, a compound semiconductor, an organic semiconductor, a complex oxide semiconductor, and a mixture thereof. The electrochromic device according to claim 1. <12> the complex oxide _{semiconductor,} SnO 2 -ZnO,
_{Nb 2 O 5 -SrTiO 3, Nb} 2 O 5 -Ta 2 O 5,
_{Nb 2 O 5 -ZrO 2, Nb} 2 O 5 -TiO 2, Ti-
_{SnO 2, Zr-SnO 2,} In-SnO 2 and Bi-
The electrochromic device according to <11>, which is selected from SnO ₂ . <13> The above <2> which is obtained by performing heat treatment before supporting the electrochromic dye on the semiconductor nanoporous layer.
The electrochromic device according to any one of <> to <12>. <14> The electrochromic device according to any one of <1> to <13>, wherein the semiconductor nanoporous layer has a thickness of 100 μm or less. <15> The electrochromic device according to any one of <1> to <14>, wherein the electrochromic dye is selected from organic compounds and metal complexes. <16> Full-colorized by any one method selected from an area gradation method by level ground mixing, a density gradation method by level ground mixing, an area gradation method by layer mixing and a density gradation method by layer mixing. <15> to the electrochromic device. <17> From <1> to <16, wherein the response speed until reaching the ultimate transmittance or the ultimate absorbance is 100 msec or less.
> Is an electrochromic device.

In the EC device according to <1>, a pair of transparent electrodes each having a semiconductor nanoporous layer formed on at least one surface thereof are arranged so that the semiconductor nanoporous layers face each other. A plurality of structural units, which sandwich an electrolyte layer containing an electrochromic dye that reversibly develops or decolorizes by at least one of an electrochemical oxidation reaction and a reduction reaction, are laminated. In the EC device, the EC dye in the electrolyte layer efficiently permeates to the surface of the semiconductor nanoporous layer formed on the surface of the transparent electrode constituting each structural unit and to the inside of the micropores in the inside thereof, thereby responding. The speed is greatly improved, the electrode area can be expanded, and the coloring amount on the electrode is increased, so that the coloring efficiency (at a lower applied voltage,
To reach a desired color density faster).

In the EC device of <2>, at least one surface of a semiconductor nanoporous layer carrying an electrochromic dye that reversibly develops or decolorizes by at least one of an electrochemical oxidation reaction and a reduction reaction. A plurality of structural units are formed by sandwiching the electrolyte layer between the pair of transparent electrodes formed in step 1 so that the semiconductor nanoporous layers face each other. In the EC device, since the EC dye is carried and immobilized on the surface and the internal fine pores of the semiconductor nanoporous layer formed on the surface of the transparent electrode which constitutes each structural unit, color development and decolorization are performed. Since there is no movement of substances (ions), the time for substance movement due to diffusion can be eliminated, the response speed is greatly improved, the electrode area can be expanded, and the amount of dye on the electrode is increased. Coloring efficiency is improved.

The EC device described in <4> is the same as the EC device described in <2>.
In <> or <3>, different EC dyes are carried for each structural unit, and by stacking them, it is possible to easily achieve black coloring or full-colorization of the light control element of the imaging device such as a camera.

The EC device according to <5> is the EC device according to <1.
> To <4>, at least one of the semiconductor nanoporous layers is formed in a multi-layered structure, which can enhance the coloring intensity and easily carry a different electrochromic dye for each layer. Full colorization can be achieved.

The EC device according to <7> above,
> Or <6>, the semiconductor nanoporous layer can be efficiently formed by laminating the semiconductor nanoporous layer at a low temperature of 150 to 200 ° C. It is possible to achieve black coloration of optical elements and full-color electronic paper and display devices.

The EC device according to <8> above,
In any one of <> to <7>, full-colorization can be easily achieved by supporting different EC dyes in each layer of the semiconductor nanoporous layer formed in the multilayer structure.

The EC device according to <9> above,
> Each of <8>, by using the EC dye and the charge transfer agent in combination, both of them can develop color at the same time on the electrode, the color density is increased, and the oxidation-reduction reaction smoothly proceeds to give a response. Speed is improved.

In the EC device of <11>, in any one of the above items <1> to <10>, as the semiconductor fine particles contained in the semiconductor nanoporous layer, a single semiconductor, an oxide semiconductor, a compound semiconductor, an organic semiconductor, By using a complex oxide semiconductor and a mixture thereof, a semiconductor nanoporous layer having micropores on the surface and inside can be formed, and the EC dye adsorption amount is increased to improve the response speed and the coloring efficiency. Is.

The <13> EC device according to any one of <2> to <12>, wherein the EC dye is subjected to heat treatment before being supported on the semiconductor nanoporous layer, whereby the surface of the semiconductor nanoporous layer is treated. It is possible to remove water and other impurities adsorbed on the surface of the porous layer, activate the surface of the porous layer, and
The dye can be efficiently adsorbed.

The EC device according to <14>,
In any one of 1> to <13>, when the thickness of the semiconductor nanoporous layer is 100 μm or less, the amount of the EC dye that can be adsorbed can be increased without lowering the transparency, and the color development can be achieved. Can improve efficiency.

[0019]

BEST MODE FOR CARRYING OUT THE INVENTION In the EC device of the present invention, (1) a pair of transparent electrodes each having a semiconductor nanoporous layer formed on at least one surface are arranged so that the semiconductor nanoporous layers face each other. An EC device in which a plurality of structural units each having an electrolyte layer containing an EC dye sandwiched therebetween are stacked, (2)
A structural unit formed by sandwiching an electrolyte layer between a pair of transparent electrodes having a semiconductor nanoporous layer supporting an EC dye formed on at least one surface so that the semiconductor nanoporous layers face each other. Is an EC device formed by stacking a plurality of layers.

A plurality of structural units constituting the EC device, preferably 2 to 4 are laminated, and by supporting the same type of EC dye on each structural unit, the coloring intensity can be adjusted and the coloring intensity can be adjusted. Can be enhanced. Also, different colors (for example, blue (B), green (G),
Full-colorization can be easily achieved by supporting an EC dye of red (R) three primary colors.

—Semiconductor Nanoporous Layer— The semiconductor nanoporous layer is formed on the surface of at least one, preferably both, of the pair of transparent electrodes, and in order to increase the surface area, an EC dye, It has fine pores capable of supporting a charge transfer agent as needed.

The specific surface area of the semiconductor nanoporous layer is 1
~ 5000 m < ² > / g is preferable, and 10-2500 m < ² > /
g is more preferred. Here, the specific surface area means the BET specific surface area obtained from the adsorption amount of nitrogen gas. If the specific surface area is too small, the amount of EC dye adsorbed may be increased, and the object of the present invention may not be achieved.

In the semiconductor nanoporous layer, at least one of the pair of transparent electrodes, preferably both, is formed in a multilayer structure, for example, a 2 to 4 layer structure, and the semiconductor nanoporous layer of the multilayer structure is of the same kind. By supporting the EC dye, the coloring intensity can be adjusted and the coloring intensity can be enhanced. Further, full-colorization can be easily achieved by carrying EC dyes of different colors (for example, the three primary colors of blue, green, and red) on each layer of the semiconductor nanoporous layer having a multilayer structure.

In the EC device of the present invention, a plurality of structural units are laminated, so that the semiconductor nanoporous layer is formed in a multi-layered structure if necessary, and the coloring intensity can be adjusted more efficiently. , Full color can be easily achieved.

The fine semiconductor particles contained in the semiconductor nanoporous layer are not particularly limited and may be appropriately selected depending on the intended purpose. Examples thereof include simple semiconductors, oxide semiconductors, compound semiconductors, organic semiconductors, and composites. Oxide semiconductor,
Alternatively, a mixture thereof may be used, and these may contain impurities as a dopant. There is no particular limitation on the form of the semiconductor, and it may be single crystal, polycrystal, amorphous, or a mixed form thereof.

Examples of the single semiconductor include silicon (Si), germanium (Ge), tellurium (Te),
And so on.

The oxide semiconductor is a metal oxide and has a semiconductor property, for example, TiO ₂ , Sn.
O ₂ , Fe ₂ O ₃ , SrTiO ₃ , WO ₃ , ZnO, Z
rO ₂ , Ta ₂ O ₅ , Nb ₂ O ₅ , V ₂ O ₅ , In ₂ O
₃ , CdO, MnO, CoO, TiSrO ₃ , KTiO
₃ , Cu ₂ O, sodium titanate, barium titanate, potassium niobate, and the like.

Examples of the compound semiconductor include cadmium sulfide, zinc sulfide, lead sulfide, silver sulfide, antimony sulfide, bismuth sulfide, cadmium selenide, lead selenide. , Cadmium telluride, zinc phosphide, gallium phosphide, indium phosphide, cadmium phosphide, gallium-arsenide selenide, copper-indium selenide, copper-indium sulfide, etc. To be

Examples of the organic semiconductor include polythiophene, polypyrrole, polyacetylene, polyphenylene vinylene, polyphenylene sulfide, and the like.

Examples of the complex oxide semiconductor include SnO ₂ —ZnO, Nb ₂ O ₅ —SrTiO ₃ and N.
_{b 2 O 5 -Ta 2 O 5} , Nb 2 O 5 -ZrO 2, Nb 2
_{O 5 -TiO 2, Ti-SnO} 2, Zr-SnO 2, B
_{i-SnO 2, In-SnO} 2, and the like. The SnO ₂ —ZnO is composed of relatively large ZnO particles (particle size: about 0.2 μm) and the surrounding is coated with SnO ₂ ultrafine particles (particle size: about 15 nm). SnO ₂ : ZnO = 70: 30 to 30:70 is preferable. The Nb ₂ O ₅ —SrTiO 3
_{3, Nb 2 O 5 -Ta 2} O 5, Nb 2 O 5 -ZrO 2,
And _Nb 2 _{O 5} complex, such as _{Nb 2 O} 5 -TiO 2, the
It is compounded so that the mass ratio with Nb ₂ O ₅ is 8: 2 to 2: 8.

The shape of the semiconductor fine particles is not particularly limited and can be appropriately selected according to the purpose. It may be spherical, nanotube-like, rod-like or whisker-like, and the shapes are different. It is also possible to mix more than one type of fine particles. In the case of the spherical particles, the average particle size is preferably 0.1 to 1000 nm, more preferably 1 to 100 nm. It should be noted that two or more kinds of fine particles having different particle size distributions may be mixed. In the case of the rod-shaped particles, the aspect ratio is preferably 2 to 50000, and 5 to 2
5000 is more preferable.

The method for forming the semiconductor nanoporous layer is not particularly limited and may be appropriately selected depending on the type of semiconductor. For example, metal anodization method, cathodic deposition method, screen printing method, sol-gel method. Method, thermal oxidation method, vacuum vapor deposition method, dc and rf sputtering method, chemical vapor deposition method, metalorganic chemical vapor deposition method, molecular beam deposition method, laser ablation method, etc., and a combination of the above methods. The semiconductor nanoporous layer can also be prepared.

-Method for forming oxide semiconductor nanoporous layer- Forming oxide semiconductor (metal oxide) nanoporous layer 1
One method is to react the metal oxide precursor in a solution containing a metal oxide precursor and a compound having one or more functional groups that interact with the metal oxide precursor to form a composite gel. Then, the first step of obtaining a colloidal dispersion sol composed of metal oxide fine particles, and applying the sol to a support,
A second step of drying or firing this to form a semiconductor nanoporous layer having fine pores on the transparent conductive film on the transparent insulating substrate (hereinafter referred to as “composite gelation method”). Sometimes.)

In the first step, since the formation reaction of the metal oxide fine particles proceeds in the gel whose diffusion is regulated, formation of coarse particles and sedimentation of particles do not occur, and the fine particles having a small particle diameter become uniform. It is possible to obtain a dispersed colloidal dispersion sol solution. In the so-called sol-gel method, when the metal oxide precursors are, for example, metal alkoxides, they undergo gelation by hydrolysis or dehydration condensation reaction.
A network of chemically strong three-dimensional bonds of -OM- (where M is a metal element and O is an oxygen element) is formed, cannot be re-solified, and once gelled. Then, it cannot be processed by means such as coating. On the other hand, in the method of obtaining a composite gel by reacting the metal oxide precursor in a solution containing the metal oxide precursor and a compound that interacts with the metal oxide precursor, By utilizing the interaction property of the compound that interacts with the body, it can be made into a sol again, and excellent processability can be provided.

Here, as the metal oxide precursor,
Examples thereof include metal compounds such as metal halides, metal complex compounds, metal alkoxides, metal carboxylates or chelate compounds which are soluble in the solvent used. Specific compounds include, for example, TiCl ₄ (titanium tetrachloride), ZnCl ₂ (zinc chloride), WCl ₆ (tungsten hexachloride), SnCl ₂ (stannous chloride), SrCl.
Metal halides such as ₆ (strontium chloride), Ti
(NO ₃ ) ₄ (titanium nitrate), Zn (NO ₃ ) ₂ (zinc nitrate), Sr (NO ₃ ) ₂ (strontium nitrate) and other nitrates, and the general formula M (OR) _n (where M is a metal element). ,
R is an alkyl group, and n is the oxidation number of the metal element. ) And metal alkoxides.

Examples of the metal alkoxide include:
Examples thereof include zinc diethoxide, tungsten hexaethoxide, vanadyl ethoxide, tin tetraisopropoxide, and strontium diisop.

For example, when a metal oxide layer of titanium oxide is formed, examples of the metal alkoxide include titanium tetraisopropoxide, titanium tetranormal propoxide, titanium tetraethoxide, titanium tetranormal butoxide, titanium tetraisobutoxide. , Titanium tetratert-butoxide and the like can be preferably used.

Examples of the functional group that interacts with the metal oxide precursor include a carboxyl group, an amino group and a hydroxyl group. The functional group that interacts with the metal oxide precursor may be one having one or more of the above functional groups such as an amic acid structure. The compound having at least one functional group that interacts with the metal oxide precursor is a carboxyl group, an amino group, a hydroxyl group,
It is a compound having one or more functional groups selected from the amino acid structure. Particularly preferred are polymer compounds. Specific examples of such low molecular weight compounds include dicarboxylic acid,
Examples thereof include diamine, diol, diamic acid and the like.

As a specific example of the polymer compound, a functional group selected from a carboxyl group, an amino group, a hydroxyl group and an amic acid structure is attached to the main chain, side chain or cross-linking portion.
Examples of the polymer compound include one or more species. The main chain structure of the polymer compound is not particularly limited, polyethylene structure, polystyrene structure, polyacrylate structure, polymethacrylate structure, polycarbonate structure, polyester structure, cellulose structure, Examples thereof include those having any structure such as a silicone structure, a vinyl polymer structure, a polyamide structure, a polyamideimide structure, a polyurethane structure, a polyurea structure, or a copolymer structure thereof.

The polymer compound having at least one functional group selected from the above-mentioned carboxyl group, amino group, hydroxyl group and amic acid structure in the main chain, side chain or cross-linking portion is a metal oxide precursor. The use of polyacrylic acid having a carboxyl group in the side chain is particularly preferable from the viewpoint that the form of interaction is appropriate. Further, the polymer compound having at least one kind of functional group that interacts with the metal oxide precursor has a carboxyl group, an amino group, a hydroxyl group, and an amic acid structure with a polymer compound having a functional group that interacts. It may be a copolymer with a polymer compound having the same main chain structure as described above. The polymer compound having one or more kinds of functional groups that interact with the metal oxide precursor has a mixed system of two or more kinds, or has a carboxyl group, an amino group, a hydroxyl group, or an amic acid structure, depending on the purpose. Alternatively, a mixed system with a polymer compound having the same main chain structure as described above may be used. The average degree of polymerization of the polymer compound having at least one functional group that interacts with the metal oxide precursor is 10
0 to 10,000,000 is preferable, and 5000 to 25
0000 is more preferable.

As the solvent, alcohols such as methanol, ethanol, isopropanol and butanol, and metal oxide precursors such as formamide, dimethylformamide, dioxane and benzene are dissolved but do not react with the metal oxide precursor. Anything can be used.

The method for forming the semiconductor nanoporous layer will be described in detail below, taking the case of using a metal alkoxide as the metal oxide precursor as an example.

First, the metal alkoxide is added to the solvent (for example, an organic solvent such as alcohol). Further, water necessary for partially hydrolyzing the metal alkoxide and acids such as hydrochloric acid, nitric acid, sulfuric acid or acetic acid as a catalyst are added. The amount of water and acids added here is
It can be appropriately selected depending on the degree of hydrolysis of the metal alkoxide used. Next, the resulting mixed solution is stirred at room temperature to 150 ° C. under a stream of dry nitrogen.
(Preferably, room temperature to 100 ° C.) is heated (or refluxed). The reflux temperature and time can also be appropriately selected according to the hydrolyzability of the metal oxide precursor used. As a result of the reflux, the metal alkoxide is in a partially hydrolyzed state. That is, since the amount of the water contained in the mixed solution is so small as not to sufficiently hydrolyze the alkoxyl group of the metal alkoxide, the metal alkoxide represented by the general formula M (OR) _n is used. In, all of the -OR groups are not hydrolyzed, resulting in a partially hydrolyzed state. The polycondensation reaction does not proceed in the partially hydrolyzed metal alkoxide. Therefore, even if a chain of -MO-M- is formed between the metal alkoxides, the metal alkoxides are in an oligomer state. The mixed solution containing the metal alkoxide in the oligomer state after the reflux is colorless and transparent and has almost no increase in viscosity.

Next, the temperature of the mixed solution after the reflux is lowered to room temperature, and the mixed solution has a polymer compound having at least one functional group selected from a carboxyl group, an amino group, a hydroxy group and an amino acid structure (preferably Is polyacrylic acid). In this case, the polymer compound, which is originally difficult to dissolve in an organic solvent such as alcohol, is easily dissolved in this mixed solution to obtain a transparent sol. It is considered that this is because the carboxyl group of the polymer compound and the metal alkoxide are bonded by a salt forming reaction to form a polymer complex compound. This transparent sol is usually
It is a colorless and transparent homogeneous solution.

An excess amount of water is further added to this transparent sol,
By maintaining the temperature at room temperature to 150 ° C., preferably at room temperature to 100 ° C. and further continuing the reaction, the transparent sol gels in about several minutes to one hour, and a cross-linked structure of the polymer compound and the metal alkoxide. A composite gel with is formed.

When the obtained composite gel is further kept at room temperature to 90 ° C. (usually about 80 ° C.) for 5 to 50 hours to continue the reaction, the composite gel is dissolved again and a semitransparent metal oxide fine particle colloidal dispersion sol is obtained. Is obtained. This is because, as the polycondensation reaction proceeds due to the hydrolysis reaction of the metal alkoxide, the salt structure of the polymer compound and the metal alkoxide is decomposed and converted into metal oxide fine particles and carboxylic acid ester. It is due to.

The semi-transparent metal oxide fine particle colloidal dispersion sol obtained as described above is applied to a transparent conductive film deposited on a transparent insulating substrate, and then dried or baked,
A metal oxide film having fine pores is formed.

The coating method can be carried out by a known method without particular limitation, and specific examples thereof include a dip coating method, a spin coating method, a wire bar method and a spray coating method. For drying, for example, air drying, drying performed using a dryer such as an oven, or vacuum freeze drying can be performed. Alternatively, a method of evaporating the solvent using a device such as a rotary evaporator may be used. In this case, the drying temperature, time and the like can be appropriately selected according to the purpose.

Depending on the drying temperature, the polymer compound or its reaction product may not be removed only by drying the metal oxide fine particle colloidal dispersion sol (removing the liquid component containing the solvent). In such a case, it is preferable to perform calcination in order to further remove them to obtain a pure metal oxide. The firing can be performed using, for example, a furnace, and the firing temperature varies depending on the type of the polymer compound having the functional group used, but a low temperature is suitable for achieving a multilayer structure. , About 100 ℃ -700
C. is preferable, and 100.degree. C. to 400.degree. C. is more preferable.

By the above firing, crystallization of the metal oxide fine particles and sintering of the metal oxide fine particles occur, and at the same time, the organic polymer component is thermally decomposed and disappears.

In the formation of the semiconductor nanoporous layer, the formation reaction of the metal oxide fine particles proceeds in the composite gel whose diffusion is regulated, so that formation of coarse particles and aggregation due to sedimentation of particles do not occur. It is possible to obtain a metal oxide fine particle colloidal dispersion sol in which ultra fine particles having a small particle size are uniformly dispersed.

Regarding the size of the metal oxide fine particles in the semiconductor nanoporous layer, the period of the metal oxide fine particle agglomerate structure, the volume ratio of the metal oxide fine particle agglomerate phase and the void phase, and the like, for example, the metal oxide Addition amount of a compound having at least one functional group that interacts with the metal oxide precursor to the precursor, and a compound having at least one functional group that interacts with the metal oxide precursor and the metal oxide precursor The ratio can be controlled to a desired degree by the ratio of the solid components of the above and the total mixed solution.

That is, when the addition amount of the metal oxide precursor and the compound having at least one functional group to be baked is increased, the volume ratio of the void phase in the obtained semiconductor nanoporous layer is increased, and the metal oxide precursor is added. When the ratio of the solid component of the compound and the compound having at least one functional group that interacts with the metal oxide precursor is reduced with respect to the entire mixed solution, the period of the obtained metal oxide fine particle agglomerate structure becomes small, and voids are formed. Although the density of the phase increases, the size of the metal oxide fine particles themselves increases.

The addition amount of the compound having at least one functional group that interacts with the metal oxide precursor to the metal oxide precursor varies depending on the ratio of the solid component to the entire mixed solution and can be appropriately selected. In general, the mass ratio is preferably 0.1 to 1, and more preferably 0.2 to 0.8. If the addition amount of the compound having at least one functional group that interacts with the metal oxide precursor to the metal oxide precursor is reduced, a dense semiconductor nanoporous layer with few macropores is likely to be formed, and the above mass ratio Is less than 0.1,
The complex gel may not be redissolved because a large three-dimensional network of -MOM is formed. On the other hand, if the addition amount is increased to exceed 1, on the other hand, a relatively large void is generated and a transparent semiconductor nanoporous layer tends to be formed.

The ratio of the solid component to the entire mixed solution varies depending on the addition amount of the metal oxide precursor and the compound having at least one functional group that interacts with the metal oxide precursor, and is appropriately selected. It is possible, but generally 1 to 10 mass% is preferable, and 2 to 5 mass% is more preferable. When the ratio is less than 1% by mass, the progress of the complex gelation reaction is slow, and the metal oxide fine particles are formed in a transparent sol state having high fluidity, and coarse particles are formed. If it exceeds%, the progress from the transparent sol to the composite gel is rapid and a uniform composite gel may not be obtained.

The method for forming the tungsten oxide porous layer will be described in more detail below, taking the case of using tungsten hexaethoxide as the metal alkoxide as an example.

First, tungsten hexaethoxide is added to alcohol to prepare a mixed solution. At this time, water and an acid as a catalyst are added to the alcohol. The water is about 0.1 times to equimolar to the tungsten hexaethoxide, and the acid is converted to the tungsten hexaethoxide. It is preferable to add about 0.05 times to 0.5 times the mol of each. Room temperature ~
Reflux under a stream of dry nitrogen with stirring at 80 ° C. The reflux temperature and time here are preferably 80 ° C. and about 30 minutes to 3 hours. As a result of this reflux, a transparent mixed solution is obtained.

In this mixed solution, tungsten hexaethoxide is in a partially hydrolyzed state and in an oligomer state. The temperature of this mixed solution is lowered to room temperature, and polyacrylic acid is added. Polyacrylic acid, which is essentially insoluble in alcohol, is easily dissolved in this mixed solution to obtain a colorless transparent sol. This is because the carboxylic acid of polyacrylic acid and tungsten hexaethoxide are bound by a salt forming reaction to form a polymer complex compound. When an excess amount of water is further added to this transparent sol and the temperature is maintained at room temperature to 80 ° C., the transparent sol gels in several minutes to 1 hour, and a composite having a crosslinked structure containing at least polyacrylic acid and tungsten hexaethoxide. A gelling is formed.

When this composite gel is kept at about 80 ° C. for 5 to 50 hours, the composite gel is dissolved again and a translucent sol is obtained. This is because, as the hydrolysis reaction and polycondensation reaction of tungsten hexaethoxide proceed, the salt structure of polyacrylic acid and tungsten hexaethoxide decomposes and changes into titanium oxide and carboxylic acid ester. .

The obtained sol solution is applied to a suitable substrate by a dip coating method or the like, and the temperature is about 100 ° C.-60 °
Heat to a high temperature of 0 ° C. By this heating, crystallization of the tungsten oxide fine particles and sintering of the tungsten oxide fine particles proceed at the same time, and at the same time, the polymer phase is thermally decomposed to form film-shaped tungsten oxide fine particles in which tungsten oxide is aggregated in a phase-separated state. Becomes

The weight ratio of polyacrylic acid to tungsten hexaethoxide is preferably 0.3 to 0.7. When the mass ratio is less than 0.3, -MO
A 3-M-large three-dimensional network may be formed and the gel may not be dissolved. If it exceeds 0.7, a relatively large void may be formed to form a transparent layer.

The ratio of the solid components of tungsten hexaethoxide and polyacrylic acid to the total mixed solution is preferably 1 to 10% by mass. When the ratio is less than 1% by mass, the progress of the complex gelation reaction is slow,
Tungsten oxide fine particles may be formed in a sol state having high fluidity, and coarse tungsten oxide fine particles may be formed. On the other hand, if it exceeds 10% by mass, the progress from the transparent sol to the composite gel is rapid and a uniform composite gel may not be obtained.

-Method for forming compound semiconductor nano-porous layer-As a method for forming the compound semiconductor nano-porous layer, there are an electrolytic deposition method, a chemical bath deposition method, a photochemical deposition method and the like. It is shown.

(Electrolytic Deposition Method) In the electrolytic deposition method, an electrode in which a transparent conductive film is formed on a transparent insulating substrate is formed in an electrolyte containing at least ions of an element to be deposited, and an electrode facing the electrode. And an electrochemical oxidation-reduction reaction are caused between these electrodes to form the compound semiconductor layer on the electrode on which the transparent conductive film is formed (Surface Technology V
ol. 49, No. 13 pages 1998).

The compound semiconductor produced in this step is, for example, CuGaS ₂ (copper gallium sulfide) or CuGaSe.
₂ (copper gallium selenide), CuGaTe ₂ (copper gallium telluride), CuInS ₂ (copper indium sulfide), C
uInSe ₂ (copper indium selenide), CuInTe
₂ (copper indium telluride), AgInS ₂ (silver indium silver sulfide), AgInSe ₂ (silver indium selenide), AgInTe ₂ (silver indium telluride), Zn
Se (zinc selenide), ZnTe (zinc telluride), C
dTe (cadmium telluride), Cu ₂ S (copper sulfide),
Cu ₂ Se (selenium copper), and the like.

As the electrolyte, a mixture of solutes such as sulfates and chlorides as raw material elements in a solvent is used, and water (pure water, distilled water, etc.) is used as a solvent of the electrolyte. However, when a voltage that hydrogen is generated by electrolysis of water is applied to the base, the solvent may be an organic substance as a non-aqueous solution. As the organic solvent, acetonitrile, dimethylformamide, propylene carbonate or the like can be used. The non-aqueous solution may use an inorganic non-aqueous solution such as liquid ammonia or liquid sulfur dioxide as the solvent.

The solute may be one that contains an element such as a sulfate or chloride that constitutes a compound semiconductor to be deposited on the electrode, and is soluble in the solvent. Examples of the sulfate include cuprous sulfate, indium sulfate, gallium sulfate, silver sulfate, zinc sulfate, cadmium sulfate and the like. Examples of chlorides include compounds such as cuprous chloride, indium chloride, gallium chloride, silver chloride, zinc chloride, and cadmium chloride, which are used as reduced solutes. The solute is not limited to the above compounds,
They may be used alone or in combination of two or more. As the solute, selenium oxide, selenium hydrogen oxide, tellurium oxide, tellurium hydrogen oxide, sodium thiosulfate, thiourea and the like can be used as an oxidized solute.

When the above-mentioned oxidized solute is used, by adjusting the hydrogen ion concentration, it is possible to promote the deposition of elemental ions contained in the oxidized solute. The hydrogen ion concentration can be adjusted with a regulator such as sulfuric acid or hydrochloric acid. The hydrogen ion concentration adjusted by the adjusting agent is preferably pH 0.9 to 4.0 and pH 1.5.
~ 2.5 is more preferable.

As the electrolyte, in addition to the above compounds, a supporting electrolyte composed of an inactive substance that does not participate in electrolytic reduction may be added to the electrolyte in order to obtain conductivity of the electrolyte. Examples of the supporting electrolyte include NaClO ₄ (sodium chlorate), LiClO ₄ (lithium chlorate), and the like. The supporting electrolyte is 0.05 to 1 mol /
It is preferable to include 1 amount.

Additives may be added to the electrolyte in order to improve the adhesion required when the deposition of the compound semiconductor proceeds. Examples of the additives include amines, alkaloids, sulfonic acids, mercaptans and sulfides.

In order to apply a voltage between the opposing electrodes arranged in the electrolyte, a reference electrode can be used with the third electrode as a voltage reference electrode. A reference electrode can also be used to control a constant voltage or current between the opposing electrodes. As the reference electrode, a standard hydrogen electrode, a saturated calomel electrode, a standard silver-silver chloride electrode, a standard mercury oxide electrode or the like can be used.

As the electrode facing the porous semiconductor layer arranged in the electrolyte, a material which is hardly dissolved by applying a voltage in a solution, that is, a material having a small ionization tendency can be used. For example, platinum (Pt), gold (A
u), silver (Ag), and the like.

The voltage applied between the opposing electrodes arranged in the electrolyte may be lower than the redox potential of the element ion of the compound containing the element forming the compound semiconductor to be deposited contained in the electrolyte. preferable.

The content of the compound contained in the electrolyte is 5
Is preferably 400 to 400 mmol / l, more preferably 5 to 20 mmol / l in the reduction type element ion deposition, and more preferably 100 to 400 mmol / l in the oxidation type element ion deposition. 20-100 degreeC is preferable and, as for the temperature of the said solution, 22-70 degreeC is more preferable.

The voltage application time for forming the compound semiconductor layer is preferably 300 to 3600 seconds, more preferably 800 to 2400 seconds.

The compound semiconductor deposited in the above step is baked and crystallized. The crystallization temperature depends on the kind of the compound semiconductor to be deposited, but is preferably 50 to 600 ° C.
50-600 degreeC is more preferable. The crystallization time is 1 to
60 minutes are preferable and 15 to 30 minutes are more preferable.

(Chemical bath deposition method) In the chemical bath deposition method, an electrode having a transparent conductive film formed on a transparent insulating substrate is placed in a solution containing at least one kind of ions to be deposited,
A compound semiconductor layer is formed on an electrode by causing a reduction reaction by adjusting the temperature of the solution and adjusting the ion concentration (Journal of Applied Phys).
ics, vol. 82, 2, 655, 1997).

In this chemical bath deposition method, elemental ions are generated by an oxidizing agent or a reducing agent, a complexing agent is used to stabilize the ions, a buffering agent is used to prevent fluctuations in hydrogen ion concentration, and By adding a stabilizer or the like for preventing spontaneous decomposition, the compound semiconductor can be deposited on the electrode on which the transparent conductive film is formed by the redox reaction thereof.
The compound semiconductor produced in this step is not particularly limited, but ZnSe (zinc selenide), ZnTe (zinc telluride), CdTe (cadmium telluride), Cu
₂ S (copper sulfide), _Cu 2 Se (selenium copper), and the like.

As the solution, a mixture of solutes such as sulfates and chlorides which become ions in a solvent is used. Water (pure water, distilled water, etc.) or the like is used as the solvent. An organic solvent can also be used, and for example, acetonitrile, dimethylformamide, propylene carbonate, etc. can be used. It is also possible to use an inorganic non-aqueous solution such as liquid ammonia or liquid sulfur dioxide.

The solute may be any so long as it contains an element such as a sulfate or a chloride that constitutes the compound semiconductor to be deposited on the electrode on which the transparent conductive film is formed. Examples of the sulfate include cuprous sulfate, indium sulfate, gallium sulfate, silver sulfate, zinc sulfate, cadmium sulfate and the like. Examples of chlorides include cuprous chloride, indium chloride, gallium chloride, silver chloride, zinc chloride and cadmium chloride. As the solute, selenium oxide, selenium hydrogen oxide, tellurium oxide, tellurium hydrogen oxide, sodium thiosulfate, thiourea and the like can also be preferably used.

When a compound as described above is used, adjusting the hydrogen ion concentration can promote the deposition of elemental ions contained in the compound. As the adjusting agent for adjusting the hydrogen ion concentration, for example, a basic compound such as sodium hydroxide or ammonium hydroxide, an inorganic acid, an organic acid or the like can be used. Further, the buffer used to suppress the fluctuation of the hydrogen ion concentration, sodium citrate sodium acetate, those of the oxycarboxylic acid type, those having a small dissociation constant of inorganic acids such as boric acid or carbonic acid, Alkali salts of organic and inorganic acids can be used. Further, as a complexing agent, ammonium hydroxide,
Sodium citrate, sodium acetate, ethylene glycol and the like can be used.

As the stabilizer, lead chlorides, sulfides, nitrides and the like can be used. The concentration of the compound containing the raw material element of the compound semiconductor in the solution is 1.0 × 10 ^−3.
~ ² mol / l is preferable, and 2.0 x 10 ^{-2 to 1} mo.
1 / l is more preferred.

The temperature of the solution is preferably 20 to 100 ° C, more preferably 22 to 70 ° C. The formation time of the compound semiconductor layer is preferably 300 to 3600 seconds, and 1
200 to 2400 seconds is more preferable.

The compound semiconductor layer deposited in the above step is baked and crystallized. The crystallization temperature depends on the kind of the compound semiconductor to be deposited, but is preferably 50 to 600 ° C.,
150-550 degreeC is more preferable. The crystallization time is 1
-60 minutes are preferable, and 15-30 minutes are more preferable.

(Photochemical Deposition Method) In the photochemical deposition method, an electrode having a transparent conductive film formed on a transparent insulating substrate is placed in a solution containing at least one kind of sodium thiosulfate and one or more metal ions. The compound semiconductor layer is formed on an electrode by irradiating ultraviolet rays to cause a photoreaction (Japan Journal Applied Ph).
ysics vol36, L1146 1997).

In this photochemical deposition method, a compound formation reaction is caused by photoexcitation of ions (thiosulfate ions, etc.) in the solution, and the film thickness can be easily controlled by the presence or absence of light irradiation and the intensity change. The compound semiconductor produced in this step is not particularly limited, but CuGaS ₂ (copper gallium sulfide), CuInS ₂ (copper indium sulfide), AgI
Examples include nS ₂ (silver indium sulfide) and Cu ₂ S (copper sulfide).

The solution used is a mixture of solutes such as sulfates and chlorides which become ions in a solvent. The solute may be any so long as it contains an element such as a sulfate or chloride that constitutes the compound semiconductor to be deposited on the electrode. Examples of the sulfate include cuprous sulfate, indium sulfate, gallium sulfate, cadmium sulfate and the like. Examples of chlorides include cuprous chloride, indium chloride, gallium chloride and cadmium chloride.

The solute is not limited to the above compounds and may be used alone or in combination of two or more. When the above-mentioned oxidation type compound is used, by adjusting the hydrogen ion concentration, it is possible to promote the deposition of the element ions contained in the oxidation type compound. The hydrogen ion concentration can be adjusted with a regulator such as sulfuric acid. The hydrogen ion concentration adjusted by the adjusting agent is preferably pH 1.5 to 4.0, and pH 2.5 to 3.5.
Is more preferable.

It is preferable to stir the solution, 60
It is preferable to stir at rpm or less. Further, the light used for the photoexcitation generates ultraviolet light by a high-pressure mercury light source lamp or the like, is condensed by a single convex lens, and is irradiated onto the electrode arranged in the solution. The single convex lens is preferably made of quartz glass.

The concentration of the compound containing the raw material element of the compound semiconductor in the solution is preferably 1.0 to 20 mmol / l, more preferably 2.0 to 10 mmol / l. The temperature of the solution is preferably 20 to 40 ° C, and 22 to 35 ° C.
Is more preferable. The formation time of the compound semiconductor layer is preferably 2400 to 4800 seconds, and 3000 to 360.
0 second is more preferable

The deposited compound semiconductor is baked and crystallized. The crystallization temperature depends on the kind of the compound semiconductor to be deposited, but is preferably 80 to 600 ° C., and 80 to 5 ° C.
00 ° C is more preferable. The crystallization time is preferably 1 to 60 minutes, more preferably 15 to 30 minutes. In particular, 80 to 400 ° C. for sulfide type, 300 to 550 for selenium type
℃, in the case of tellurium series, 400 ~ 600 ℃ is preferable.

—Method for Forming Complex Oxide Semiconductor Nanoporous Layer— The complex oxide semiconductor nanoporous layer is obtained by further forming an oxide semiconductor on the oxide semiconductor nanoporous layer formed by the above method by a sol-gel method. Examples thereof include a method of forming a nanoporous layer and forming a composite, or a method of applying a paste in which two kinds of oxide semiconductor particles are mixed onto an electrode.

Specifically, acetic acid is added dropwise to the oxide semiconductor colloid aqueous solution, and the oxide semiconductor powder and alcohol to be composited are added little by little to the gelled solution which is well mixed in a mortar and mixed well. Further, a surfactant is added and mixed well, and this is mixed with a fluorine-doped tin oxide conductive film glass (FTO) electrode on a hot plate (100 to 120).
(° C.) by spray coating and firing, the crystallization of the semiconductor fine particles and the firing of the semiconductor fine particles proceed to form a complex oxide semiconductor nanoporous layer having a desired porosity.

The semiconductor nanoporous layer may be formed by applying a multi-layered dispersion of semiconductor fine particles having different particle sizes or a multi-layered coating layer containing different kinds of semiconductor fine particles (or different binders or additives). You can also Multi-layer coating is effective even when the film thickness is insufficient by one coating. An extrusion method or a slide hopper method is suitable for the multilayer coating. In the case of applying multiple layers, the multiple layers may be applied at the same time, or may be applied repeatedly several times to ten or more times. Furthermore, a screen printing method can also be preferably used if it is applied in sequence. In this case, it is preferable to perform a process of adsorbing and carrying an EC dye on each semiconductor nanoporous layer formed in a multi-layer structure. Different EC dyes may be adsorbed and carried on each layer, or the same EC dye may be adsorbed and carried on each layer. It doesn't matter.

The semiconductor nanoporous layer is heat-treated (for example, 10 to 100 ° C. to 550 ° C.) before supporting the EC dye.
It is preferable to do this for a minute. This makes it possible to remove moisture and other impurities adsorbed on the surface of the semiconductor nanoporous layer, activate the surface of the porous layer, and efficiently adsorb the EC dye.

The thickness of the semiconductor nanoporous layer is 100.
μm or less is preferable, 50 μm or less is more preferable, and 2
It is more preferably 0 μm or less. If the thickness of the porous layer is too thin, the amount of EC dye that can be adsorbed may decrease. On the other hand, if it is too thick, the transparency will decrease and E
In some cases, the charge injected into the C element may increase in loss.

-EC Dye- The EC dye is carried on the surface and inside the micropores of the semiconductor nanoporous layer and, if necessary, is contained in a state of being dissolved or dispersed in the electrolyte layer. It is preferable. The EC dye is not particularly limited as long as it exhibits a function of developing or decoloring by at least one of an electrochemical oxidation reaction and a reduction reaction, and it can be appropriately selected according to the purpose. For example, an organic compound, a metal Suitable examples include complexes. These may be used alone or in combination of two or more.

Examples of the metal complex include Prussian blue, metal-bipyridyl complex, metal phenanthroline complex, metal-phthalocyanine complex, metaferricyanide, and derivatives thereof.

Examples of the organic material include (1) pyridine compounds, (2) conductive polymers, (3) styryl compounds, (4) donor / acceptor type compounds,
(5) Other organic dyes and the like.

Examples of the pyridine compounds (1) include viologen, heptylviologen (diheptylviologen dibromide, etc.), methylenebispyridinium, phenanthroline, azobipyridinium, 2,2.
-Bipyridinium complex, quinoline / isoquinoline, and the like.

Examples of the conductive polymer (2) include polypyrrole, polythiophene, polyaniline, polyphenylene diamine, polyaminophenol, polyvinylcarbazole, polymer viologen polyion complex, TTF, and derivatives thereof.

Examples of the above-mentioned (3) styryl compounds include 2- [2- [4- (dimethylamino) phenyl]
Ethenyl] -3,3-dimethylindolino [2,1-
b] oxazolidine, 2- [4- [4- (dimethylamino) phenyl] -1,3-butadienyl] -3,3-dimethylindolino [2,1-b] oxazolidine, 2-
[2- [4- (dimethylamino) phenyl] ethenyl]
-3,3-Dimethyl-5-methylsulfonylindolino [2,1-b] oxazolidine, 2- [4- [4- (dimethylamino) phenyl] -1,3-butadienyl]-
3,3-Dimethyl-5-sulfonylindolino [2,1
-B] oxazolidine, 3,3-dimethyl-2- [2-
(9-Ethyl-3-carbazolyl) ethenyl] indolino [2,1-b] oxazolidine, 2- [2- [4-
(Acetylamino) phenyl] ethenyl] -3,3-dimethylindolino [2,1-b] oxazolidine, and the like.

Examples of the above-mentioned (4) donor / acceptor type compounds include tetracyanoquinodimethane and tetrathiafulvalene.

Examples of the (5) other organic dyes include carbazole, methoxybiphenyl, anthraquinone, quinone, diphenylamine, aminophenol,
Tris-aminophenylamine, phenylacetylene, cyclopentyl compound, benzodithiolium compound, squarylium salt, cyanine, rare earth phthalocyanine complex, ruthenium diphthalocyanine, merocyanine, phenanthroline complex, pyrazoline, redox indicator, p
H indicators, derivatives thereof, and the like.

Among these, viologen, heptyl viologen (diheptyl viologen dibromide, etc.)
Viologen-based dyes such as are suitable. Also, the above E
As the C dye, it shows a colorless to ultra-light color in the oxidized state,
Reducing color type that develops color in the reduced state, colorless to ultra-light color in the reduced state, oxidative color type that develops in the oxidized state, coloration in both the reduced state and the oxidized state, and several types depending on the degree of reduction or oxidation. It may be of any of the multicolor-developing type that develops color, and can be appropriately selected according to the purpose.

The combination of two or more of the EC dyes is not particularly limited and may be appropriately selected depending on the intended purpose. For example, a combination of viologen and polyaniline, polypyrrole and polymethylthiophene, and the like. And a combination of polyaniline and Prussian blue.

The method for supporting the EC dye on the surface and inside of the semiconductor nanoporous layer is not particularly limited,
Known techniques can be used. For example, a dry process such as a vacuum vapor deposition method, a coating method such as spin coating, an electric field deposition method, an electric field polymerization method, and a natural adsorption method of immersing in a solution of a compound to be supported can be appropriately selected. Among them, the natural adsorption method is
The functional molecules can be surely supported evenly throughout the fine pores of the metal oxide layer, no special equipment is required, and in many cases it is about a monomolecular layer and an excessive amount is needed. It is a preferable method because it has many advantages such as lack.

Specifically, a method of immersing a well-dried transparent substrate having a semiconductor nanoporous layer in a solution of an EC dye or applying a solution of the dye to the semiconductor nanoporous layer can be used. In the former case, a dipping method, a dipping method, a roller method, an air knife method or the like can be used. In the case of the dipping method, the dye may be adsorbed at room temperature, or may be heated under reflux as described in JP-A-7-249790. The latter coating method includes a wire bar method, a slide hopper method, an extrusion method, a curtain method, a spin method and a spray method.

As a solvent for dissolving the EC dye, for example, water, alcohols (methanol, ethanol, t
-Butanol, benzyl alcohol, etc.), nitriles (acetonitrile, propionitrile, 3-methoxypropionitrile, etc.), nitromethane, halogenated hydrocarbons (dichloromethane, dichloroethane, chloroform,
Chlorobenzene, etc., ethers (diethyl ether,
Tetrahydrofuran etc.), dimethyl sulfoxide, amides (N, N-dimethylformamide, N, N-dimethylacetamide etc.), N-methylpyrrolidone, 1,3-dimethylimidazolidinone, 3-methyloxazolidinone, esters ( Ethyl acetate, butyl acetate, etc.), carbonates (diethyl carbonate, ethylene carbonate, propylene carbonate, etc.), ketones (acetone, 2-butanone, cyclohexanone, etc.), hydrocarbons (hexane, petroleum ether, benzene, toluene, etc.) And mixed solvents of these.

The adsorbed amount of the EC dye is 0.01 to 100 m per unit surface area (1 m ² ) of the semiconductor nanoporous layer.
mol is preferred. The amount of the EC dye adsorbed on the semiconductor fine particles is 0.01 to 10 per 1 g of the semiconductor fine particles.
It is preferably in the range of 0 mmol. Further, the concentration of the EC dye in the electrolyte is preferably 0.001 to 2 mol / l, more preferably 0.005 to 1 mol / l.

—Charge Transfer Agent— Like the EC dye, the charge transfer agent is carried on the surface and inside the micropores of the semiconductor nanoporous layer, and
If necessary, it is preferably contained in a state of being dissolved or dispersed in the electrolyte layer. The charge transfer agent can be loaded on the semiconductor nanoporous layer by the same method as for the EC dye. When the charge transfer agent and the EC dye are used in combination, a coloring effect by simultaneous color development of the both and an interaction between the two can smoothly proceed the redox reaction to further improve the color development efficiency.

The charge transfer agent is not particularly limited and may be appropriately selected depending on the intended purpose, but those exhibiting electrochromic properties are preferable, and examples thereof include hydrazone, phenothiazine, [β- (10- Phenothiazyl) -propoxy] phosphonic acid (phenothiazine derivative), and the like, and one of these may be used alone or two or more thereof may be used in combination.

The amount of the charge transfer agent adsorbed is 0.01 to 100 per unit surface area (1 m ² ) of the semiconductor nanoporous layer.
mmol is preferred. The amount of the charge transfer agent adsorbed on the semiconductor fine particles is 0.01 to 1 g of the semiconductor fine particles.
It is preferably in the range of 100 mmol. The concentration of the charge transfer agent in the electrolyte is preferably 0.001 to 2 mol / l, more preferably 0.005 to 1 mol / l.

—Electrolyte Layer— The electrolyte layer is not particularly limited and may be appropriately selected depending on the intended purpose, but preferably contains an EC dye and a charge transfer agent. As the EC dye and the charge transfer agent, Although it can be appropriately selected and used from the above-mentioned ones, the same one as the EC dye or the charge transfer agent supported on the semiconductor nanoporous layer is preferable. The form of the electrolyte layer may be liquid, solid, or gel.

(1) Liquid Electrolyte Layer When the electrolyte layer is a liquid, I ⁻ / I ₃ ⁻ , Br ⁻
It is preferable to use a charge-transporting substance such as an electrolyte, which contains a redox pair (oxidation-reduction pair) such as / Br ₃ ⁻ and a quinone / hydroquinone pair, and which can be transported between electrodes at a sufficient rate in a solvent.

Examples of the electrolyte include iodine, bromine, LiI, NaI, KI, CsI, CaI ₂ , and LiB.
Metal halides such as r, NaBr, KBr, CsBr, CaBr ₂ , tetraethylammonium iodide, tetrapropylammonium iodide, tetrabutylammonium iodide, tetramethylammonium bromide, tetraethylammonium bromide, tetrabutylammonium bromide, etc. At least one of halogenated salts of ammonium compounds, alkyl viologens such as methyl viologen chloride and hexyl viologen bromide, polyhydroxybenzenes such as hydroquinone and naphthohydroquinone, and iron complexes such as ferrocene and ferrocyanate can be used. However, the present invention is not limited to this. In addition, when a plurality of electrolytes that previously generate a redox pair (oxidation-reduction pair) are mixed and used, such as a combination of iodine and lithium iodide, it is possible to improve the performance of the EC element, particularly the current characteristics. Become. Among these, a combination of iodine and an ammonium compound, a combination of iodine and a metal iodide, and the like are preferable.

As a solvent for dissolving these electrolytes,
Carbonate compounds such as ethylene carbonate and propylene carbonate, ethers such as dioxane, diethyl ether and ethylene glycol dialkyl ether,
Alcohols such as methanol, ethanol, isopropyl alcohol, ethylene glycol, propylene glycol and polyethylene glycol, nitriles such as acetonitrile and benzonitrile, aprotic polar solvents such as dimethylformamide, dimethylsulfoxide, propylene carbonate and ethylene carbonate, water, etc. Can be used, but is not limited thereto.

The electrolyte concentration of the electrolyte in the solvent is preferably 0.001 to 2 mol / l,
More preferably, it is 005 to 1 mol / l. When the electrolyte concentration is less than 0.001 mol, the function as a carrier does not work sufficiently, and the characteristics may deteriorate. On the other hand, when it exceeds 2 mol / l, the above-mentioned effect corresponding to it does not appear, and the viscosity of the electrolyte solution becomes high, which may lead to a decrease in current.

(2) In the case of solid electrolyte layer When the electrolyte layer is solid, ionic conductivity or electron
It may be any conductive material, for example, A
gBr, AgI, CuCl, CuBr, CuI, Li
I, LiBr, LiCl, LiAlCl_Four, LiAlF
_Four, Halides such as AgSBr, C₅H₅NHAg
₅I₆, Rb_FourCu₁₆I₇Cl_Thirteen, Rb_ThreeCu₇C
l₁₀Inorganic condensate, LiN, Li₅NI_Two, Li₆N
Br_ThreeSuch as lithium nitride and its derivatives, Li_TwoS
O_Four, Li_FourSiO_Four, Li_ThreePO_FourLithium acid etc
Phosphate, ZrO_Two, CaO, Gd_TwoO_Three, HfO_Two, Y
_TwoO_Three, Nb_TwoO₅, WO_Three, Bi_TwoO_Three, And these
Solid solution oxides, CaF_Two, PbF_Two, SrF_Two,
LaF_Three, TISn_TwoF₅, CeF_ThreeFluoride such as C
u _TwoS, Ag_TwoS, Cu_TwoSe, AgCrSe_TwoEtc.
Rucogenide, perfluorosulfur in vinyl fluoride polymer
Polymers containing phonic acid (eg Nafion), organic
As a cargo-transporting substance, polythiophene, polyaniline,
Compounds such as polypyrrole, fragrances such as triphenylamine
Carbazo such as group amine compounds and polyvinylcarbazole
Silane compound such as a polyol compound or polymethylphenylsilane
Can be used, but is not limited to
Absent.

(3) Gel Electrolyte Layer When the electrolyte layer is in a gel state, a polymer addition, an oil gelling agent addition, and polyfunctional monomers can be mixed with the electrolyte and the solvent and used. When gelation is performed by adding the polymer, “Polymer E
"lectrolyte Revews-1 and 2"
(J.R. MacCallum and CA Vincen
ELSEVIER APPLIED SCI
ENCE) and the like can be used, but polyacrylonitrile, polyvinylidene fluoride and the like are particularly preferable. When gelation is performed by adding the oil gelling agent, “J. Chem Soc.
pan, Ind. Chem. Sec. , 46,779
(1943) "," J. Am. Chem. Soc., 1 ".
11, 5542 (1989), "" J. Chem. So.
c. Chem. Commun. , 1993, 39
0 "," Angew. Chem. Int. Ed. Eng.
l. , 35, 1949 (1996) "," Chem. L.
ett. , 1996, 885 "," J. Chem. So.
c. Chem. Commun. , 1997, 545 "
Although the compounds described in, etc. can be used, a compound having an amide structure in the molecular structure is particularly preferable.

It is also possible to use a solid electrolyte layer formed into a film by polymerizing a mixed solution of a matrix material and a supporting electrolyte. —Supporting Electrolyte— The supporting electrolyte is appropriately selected depending on the intended purpose without any limitation, and it may be an inorganic electrolyte or an organic electrolyte. These may be used alone or in combination of two or more,
It may be a commercially available product or may be appropriately synthesized.

Examples of the inorganic electrolyte include inorganic acid anion-alkali metal salt, alkali metal salt, alkaline earth metal, and the like. Among these, inorganic acid anion-alkali metal salt is preferable, and inorganic acid lithium Salts are more preferred.

As the inorganic acid anion-alkali metal salt
For example, XAsF₆, XPF ₆, XBF_Four, XC
10_Four, Etc. (However, in these, X
Represents H, Li, K or Na. ), Specifically oversalt
Preference is given to lithium oxalate and the like.

Examples of the alkali metal salt include L
iI, KI, LiCF ₃ SO ₃ , LiPF ₆ , LiCl
O ₄ , LiBF ₄ , LiSCN, LiAsF ₆ , NaC
_{F 3 SO 3, NaPF 6,} NaClO 4, NaI, Na
_{BF 4, NaAsF 6, KCF 6} SO 3, KPF 6, and the like.

Examples of the organic electrolyte include organic acid anion-alkali metal salts, quaternary ammonium salts, anionic surfactants, imidazolium salts, and the like. Among these, organic acid anion-alkali metal salts Salts are preferred, and organic acid lithium salts are more preferred.

Examples of the organic acid anion-alkali metal salt include XCF ₃ SO ₃ and XC _n F _{2n + 1} SO.
_{3 (n = 1~3), XN} (CF 3 SO 2) 2, XC (C
_{F 3 SO 2) 3, XB} (CH 3) 4, XB (C 6 H 5)
₄ , etc. (wherein X is H,
Li, K or Na), specifically, lithium polymethacrylate is suitable.

As the quaternary ammonium salt, for example,
For example, [CH_Three(CH_Two)_Three]_FourN ・ Y, C_nH_{2n + 1}
N (CH_Three)_Three・ Y (n = 10 to 18), (C_nH
_{2n + 1}) _TwoN (CH_Three)_Two・ Y (n = 10 to 18),
(However, in these, Y is B
F_Four, PF₆, ClO_Four, F, Cl, Br or OH
You )

As the anionic surfactant, for example,
For example, C_nH_{2n + 1}COO · X (n = 10-18), C
_nH_{2n + 1}OC_mH_2mCOO · X (n = 10 to 1
8, m = 10-18), C₁₀H₇COO / X, C_nH
_{2n + 1}C₁₀H₆COO · X (n = 10-18), C
_nH_{2n + 1}SO_Three・ X (n = 10 to 18), C_nH_{Two
n + 1}OC_mH_2mSO_Three・ X (n = 10 to 18, m =
10-18), C₁₀H ₇SO₈・ X, C_nH_{2n + 1}
C₁₀H₆SO_Three・ X (n = 10 to 18), C_nH
_{2n + 1}OSO_Three・ X (n = 10 to 18), etc.
(However, in these, X is H, Li, K or
Represents Na. ).

The supporting electrolyte preferably contains an inorganic acid lithium salt and an organic acid lithium salt.

—Matrix Material— The matrix material is appropriately selected depending on the intended purpose without any limitation, and examples thereof include a polymer compound having a hetero atom.

Examples of the polymer compound having a hetero atom include a polymer compound having an oxygen atom, a polymer compound having a nitrogen atom, a polymer compound having a sulfur atom, and a polymer compound having a halogen atom. Can be mentioned.

As the polymer compound having the oxygen atom
Is, for example, R¹-(OCH_TwoCH _Two)_nOR^Two(N
Represents an integer, R¹Is an ethylene group, styrene group,
Ropylene group, butene group, butadiene group, vinyl chloride group,
Vinyl acetate group, acrylic acid group, methyl acrylate group,
Tacrylic acid group, methyl methacrylate group, methyl vinyl chloride
R represents a ton group, an acrylamide group, etc.^TwoIs H, CH
_ThreeOr R¹Represents ) And the like are preferred.
Specifically, polyethylene glycol, polyp
Ropylene glycol, non-polyethers (eg poly
(3-hydroxypropionic acid), polyvinyl acetate),
And the like.

Examples of the polymer compound having a nitrogen atom include R ^1- (NHCH ₂ CH ₂ ) _n NH-R ²
(N represents an integer, R ¹ represents an ethylene group, a styrene group, a propylene group, a butene group, a butadiene group, a vinyl chloride group, a vinyl acetate group, an acrylic acid group, a methyl acrylate group, a methacrylic acid group, or methacrylic acid. Represents a methyl group, a methyl vinyl ketone group, an acrylamide group, etc., and R ² is
Represents H, CH ₃ or R ¹ . And the like. Specific examples thereof include polyethyleneimine, poly-N-methylethyleneimine, and polyacrylonitrile.

As the polymer compound having the sulfur atom
Is, for example, R¹-(SCH_TwoCH _Two)_nSR^Two(N
Represents an integer, R¹Is an ethylene group, styrene group,
Ropylene group, butene group, butadiene group, vinyl chloride group,
Vinyl acetate group, acrylic acid group, methyl acrylate group,
Tacrylic acid group, methyl methacrylate group, methyl vinyl chloride
R represents a ton group, an acrylamide group, etc.^TwoIs H, CH
_ThreeOr R¹Represents ) And the like are preferred.
Specifically, polyalkylene sulfides,
And so on.

The molecular weight of the matrix material is not particularly limited and may be appropriately selected depending on the intended purpose. However, the lower the molecular weight is, the more likely it is to have fluidity at room temperature.
From the viewpoint of film formability, it is preferably low, and for example, the number average molecular weight is preferably 1,000 or less.

The amount of the matrix material to be used in the electrolyte layer is preferably such that the molar ratio with the supporting electrolyte (matrix material: supporting electrolyte) is 70:30 to 5:95, and 50:50 to 10. : 90 is more preferable, and 50:50 to 20:80 is particularly preferable.

The molar ratio means the ratio of the molar amount of the matrix material to the molar amount of the ions of the supporting electrolyte. The molar amount of the matrix material means a molar amount calculated by converting the monomer unit of the polymer compound into one molecule.

The film-like solid electrolyte layer is prepared by adding a small amount of a polymerization initiator such as benzoyl peroxide or azobisisobutyronitrile to a mixed solution of the matrix material and a supporting electrolyte, and then thinly rolling it. It can be produced by carrying out polymerization or by adding a photopolymerization initiator such as Irgacure and polymerizing by irradiation with ultraviolet rays. The thickness of the solid electrolyte film is usually 3
It is 0 to 500 μm, preferably 50 to 200 μm.

—A Pair of Transparent Electrodes— The pair of transparent electrodes is not particularly limited as long as it is transparent and conducts electricity, and can be appropriately selected depending on the purpose. For example, indium tin oxide (ITO). , Tin oxide (NESA), fluorine-doped tin oxide (FT
O), indium oxide, zinc oxide, platinum, gold, silver, rhodium, copper, chromium, carbon and the like. Among these, fluorine-doped tin oxide (FTO) and indium tin oxide (IT) have low surface resistance, good heat resistance, chemical stability, and high light transmittance.
O) is preferred.

The surface resistance of the conductive substrate is preferably lower as described above, and a specific surface resistance value is preferably 100 Ω / cm ² or less, preferably 10 Ω / cm.
² or less is more preferable. The thickness of the transparent electrode is not particularly limited and may be appropriately selected depending on the intended purpose. In the case of the transparent electrode, it is, for example, 0.1 μm.
Above all, it is generally 0.1 to 20 μm.

—Support— The support can be used as a base material or the like on which the transparent electrode is provided, and its material, shape, structure, size, etc. are not particularly limited and can be appropriately designed. . Preferable examples of the support include a glass plate and a polymer film. Materials for the polymer film include tetraacetyl cellulose (TAC), polyethylene terephthalate (PET), polyethylene naphthalate (PEN), syndiotactic polystyrene (SPS), polyphenylene sulfide (PPS), polycarbonate (PC), polyarylate ( PAr),
Examples thereof include polysulfone (PSF), polyester sulfone (PES), polyetherimide (PEI), cyclic polyolefin, and brominated phenoxy.

-Other members-The other members are not particularly limited and may be appropriately selected depending on the application of the EC device. For example, spacers, sealing members, lead wires, reflecting means, etc. Is mentioned.

The EC apparatus of the present invention is not particularly limited, and any one is selected from an area gradation method by level ground mixing, a density gradation method by level ground mixing, an area gradation method by layer mixing and a density gradation method by layer mixing. It is preferable to use a full color by the above method.

The area gradation method by the above-mentioned level ground mixing is a method of expressing a color image on the same principle as that of halftone dots on a printed matter. For example, a large number of minute pixels for coloring R (red), G (green), and B (blue) are provided in a plane, and the change in color density of each pixel does not have a gradation and color is generated by turning on / off a constant density. A color image is represented by a difference in area (for example, when the applied voltage and the applied time are constant).

The density gradation method based on the level ground mixing is a method of expressing a color image on the same principle as the halftone dot of the printed matter as described above. However, since the color density of each pixel can have gradation, the color density can be controlled by controlling the applied voltage and the application time to control the amount of charge injected into the cell.

The area gradation method based on the above-mentioned layer mixture is a method of expressing a color image on the same principle as the halftone dot of the printed matter as described above, but since cells of three colors are vertically laminated in the same pixel, Pixel density is relaxed as compared with the area gradation method based on flatland mixing.

The density gradation method by the layer mixture is a coloring method similar to the density gradation method by the plain mixture, and is a full-color expression method similar to silver salt photography.

The EC device varies depending on the application,
In the case of a transmissive element, the response speed until reaching the ultimate transmittance is preferably 100 msec or less, more preferably 10 msec or less. Further, in the case of a reflective element, the response speed until reaching the ultimate absorbance is preferably 100 msec or less,
It is more preferably 10 msec or less.

An example of the EC device of the present invention is shown in FIG.
As shown in 2, the transparent electrode 10 having the semiconductor nanoporous film 20 carrying the EC dye 25 on the surface and the transparent electrode having the semiconductor nanoporous film 22 carrying the EC dye 25 on the surface An example is one in which three structural units 40 are laminated such that the electrolyte layer 30 is sandwiched between the semiconductor nanoporous film 20 and the semiconductor nanoporous film 22. The transparent electrode 10 and the transparent electrode 12 are connected by a lead wire 60 and connected to a power source 50.

Further, as shown as an example in FIGS.
A transparent electrode 10 having a two-layered semiconductor nanoporous film 20 carrying a C dye 25 on its surface, and an EC dye 25
The electrolyte layer 30 is interposed between the semiconductor nanoporous membrane 22 having the two-layer structure and the transparent electrode 12 provided on the surface so that the electrolyte layer 30 is sandwiched between the semiconductor nanoporous membrane 20 and the semiconductor nanoporous membrane 22. An example is one in which three of the structural units 40 thus formed are stacked. The transparent electrode 10 and the transparent electrode 1
2 is connected by a lead wire 60 and is connected to a power source 50.

The EC device shown in FIGS. 1 to 4 has the transparent electrode 10
A voltage is applied between the transparent electrode 12 and the transparent electrode 12 to cause the EC dye 25 carried on the semiconductor nanoporous film to develop and disappear.

The voltage for forming an image in the EC device is appropriately selected depending on the intended purpose without any limitation, but it is preferably about 0.5 to 10 V, preferably about 1 to 5 V. Is more preferable.

The EC device of the present invention can be suitably used in various fields. For example, ECD (Elect)
a large display board such as a stock price display board, an antiglare mirror, a light control element such as a light control glass, a low voltage drive element such as a touch panel type key switch,
It can be suitably used for diaphragm devices, optical switches, optical memories, electronic paper, electronic albums, and the like.

[0154]

EXAMPLES Examples of the present invention will be described below, but the present invention is not limited to these examples.

(Example 1) Titanium oxide paste (Sol
Ti-Nanoxide HT manufactured by Aronix was applied on an ITO glass substrate using a doctor blade and dried. The obtained dried product was baked in air at 550 ° C. for 30 minutes to form a porous film having a thickness of 10 μm on a glass substrate.

Then, using the above substrate as an EC dye,
Dye adsorption treatment by immersing in 0.02M 2- {2- [4- (dimethylamino) phenyl] ethenyl} -3,3-dimethyl-5-phosphonoindolino [2,1-b] oxazoline in acetonitrile And dried at room temperature to prepare a magenta dye-bonded electrode.

Using the obtained dye-bonded electrode and an ITO glass substrate as an electrode paired with the dye-bonded electrode, the dye-bonded electrode was brought into contact with an electrolyte solution to assemble a magenta coloring EC element. Between both poles is 0.
It was set to 5 mm. A 0.2 M tetrabutylammonium perchlorate propylene carbonate solution was used as the electrolyte solution. The size of the pair of electrodes produced was 5 mm × 5 mm.

Next, using 2- {2- [4- (dimethylamino) phenyl] -1,3-butadienyl} -3,3-dimethyl-5-carboxyindolino [2,1-b] oxazoline. Then, the same operations as those for the magenta color-developing EC element were carried out to produce a cyan color-developing EC element.

Further, using 2- {2- [4- (methoxy) phenyl] ethenyl} -3,3-dimethyl-5-phosphonoindolino [2,1-b] oxazoline, the above magenta coloring EC The same operation as for the device was performed to produce a yellow color EC device.

The above three types of EC elements are used as structural units, three structural units are laminated, and each pair of electrodes is connected by a lead wire (a dye-bonding electrode for the anode and an ITO glass substrate for the cathode).
Then, a display device was manufactured.

In this display device, when a voltage of 3 V was applied to the magenta color-forming structural unit at room temperature, the styryl derivative was oxidized at the anode and the colorless state changed to magenta. Next, when a voltage of 3 V was applied to the cyan color-forming structural unit at room temperature, the styryl derivative was oxidized at the anode and changed from colorless to cyan. When a voltage of 3 V was applied to the yellow color forming structural unit at room temperature, the styryl derivative was oxidized at the anode,
Colorless changed to yellow.

Further, when a voltage of 3 V was simultaneously applied to the magenta color-forming structural unit and the cyan color-forming structural unit at room temperature, the styryl derivative was oxidized at the anodes of the respective structural units to develop magenta and cyan colors, and the total It changed from colorless to blue. Next, when a voltage of 3 V was applied simultaneously to the magenta color-forming structural unit and the yellow color-forming structural unit at room temperature, the styryl derivative was oxidized at the anode of each structural unit to develop magenta and yellow, and the overall colorless to colorless It turned red. When a voltage of 3 V was simultaneously applied to the cyan color forming structural unit and the yellow color forming structural unit at room temperature, the styryl derivative was oxidized at the anodes of the respective structural units to form cyan and yellow colors, and overall colorless to green. Changed to.

Furthermore, when a voltage of 3 V was simultaneously applied to the three color-forming structural units at room temperature, the styryl derivative was oxidized at the anodes of the respective structural units to develop magenta, cyan, and yellow, and the overall color was colorless. It turned black.

The response speed to reach the ultimate transmittance was 80 msec in all cases. Even when the application of voltage was stopped, color development continued for 600 seconds or longer. Further, even when the color development-color erasing was repeated 10,000 times, the color strength during color development and the transparency during color erasure hardly changed.

(Example 2) In Example 1, the following electrolyte solution was used as an electrolyte, and this electrolyte solution was applied on one dye-bonding electrode with a spin coater to a thickness of 800.
An EC device was prepared in the same manner as in Example 1, except that the film-like electrolyte layer was formed by applying the solution to a thickness of μm and heating at 60 ° C. for 6 hours.

-Electrolyte Solution- In a solution of 67 g of lithium hydroxide dissolved in 27 ml of methanol, 7.68 g of methacrylic acid was added to 12 m of methanol.
The solution dissolved in 1 was added dropwise with stirring. Furthermore, the mixed solution obtained here was added dropwise to 2 liters of acetone,
The precipitate was collected by filtration, washed with acetone, and vacuum dried to obtain 2.38 g of white powder of lithium methacrylate. Next, 50 ml of a 1M aqueous solution of lithium methacrylate was prepared, and 1% by mass of potassium peroxodisulfate was added to this, and the mixture was kept at 70 ° C. for 24 hours in a nitrogen atmosphere to obtain lithium methacrylate. Was polymerized. After the completion of the polymerization reaction, reprecipitation was performed using 500 ml of methanol, and the precipitate was collected and dried to synthesize 1.73 g of white powder of lithium polymethacrylate. Next, lithium iodide: lithium perchlorate: the synthesized polylithium methacrylate = 50: 30: 20 (molar ratio) was used, and polyethylene glycol (number average molecular weight = 600) was used as the matrix material ( Ethylene oxide unit of polyethylene glycol: lithium ion = 5
1:49 (molar ratio)), these were dissolved in water.

When a voltage of 3 V was applied to the magenta color-forming structural unit at room temperature in the obtained display device,
The styryl derivative was oxidized at the anode and changed from colorless to magenta. Next, when a voltage of 3 V was applied to the cyan color-forming structural unit at room temperature, the styryl derivative was oxidized at the anode and changed from colorless to cyan. When a voltage of 3 V was applied to the yellow color-forming structural unit at room temperature, the styryl derivative was oxidized at the anode and changed from colorless to yellow.

Furthermore, when a voltage of 3 V was applied simultaneously to the magenta color-forming structural unit and the cyan color-forming structural unit at room temperature, the styryl derivative was oxidized at the anode of each structural unit to develop magenta and cyan colors, and overall. It changed from colorless to blue. Next, when a voltage of 3 V was applied simultaneously to the magenta color-forming structural unit and the yellow color-forming structural unit at room temperature, the styryl derivative was oxidized at the anodes of the respective structural units to form magenta and yellow, and the overall colorless to It turned red. When a voltage of 3 V was simultaneously applied to the cyan color-forming structural unit and the yellow color-forming structural unit at room temperature, the styryl derivative was oxidized at the anodes of the respective structural units to form cyan and yellow colors, and overall colorless to green. Changed to.

Furthermore, when a voltage of 3 V was simultaneously applied to the three color-forming structural units at room temperature, the styryl derivative was oxidized at the anodes of the respective structural units to develop magenta, cyan, and yellow, and the overall colorless to It turned black.

The response speed until reaching the ultimate transmittance was 100 msec in all cases. Even when the application of voltage was stopped, color development continued for 600 seconds or longer. Further, even when the color development-color erasing was repeated 10,000 times, the color strength during color development and the transparency during color erasure hardly changed.

Example 3 -Porous TiO ₂ Electrode- Titanium tetraisopropoxide (6.41 g) was diluted with 20 ml of ethanol, and 0.514 g of nitric acid having a specific gravity of 1.38 and 0.2 ml of water were added with stirring. It was The above mixing operation was performed in a dry nitrogen atmosphere. This mixture is at 80 ℃
The temperature was raised to 2, and reduction was performed for 2 hours under a stream of dry nitrogen to obtain a colorless and transparent sol liquid. After cooling the sol liquid to room temperature, 0.1 g of polyacrylic acid was added to 2 g of the sol liquid while stirring.
Was dissolved. 2 ml of water was further added to the obtained sol liquid to obtain a colorless, transparent and uniform sol liquid. The sol solution was sealed in a glass container and heated to 80 ° C. The sol liquid gelled in about 5 minutes and became a substantially transparent and uniform gel. When kept at 80 ° C. for a further 15 hours, the gel was dissolved again and became a whitish translucent sol liquid.

This sol solution was subjected to IT by spin coating.
It was coated on an O glass substrate, heated to 450 ° C., held for 20 minutes, and baked. This coating and baking process was repeated 20 times to form an electrode made of a porous TiO ₂ film having a film thickness of 3.5 μm. As a result of examining the crystal structure of the obtained film by X-ray diffraction, it was confirmed that anatase type titanium oxide was formed. When the fine structure of the film was examined by SEM observation, a phase-separated aggregate structure was formed. The specific surface area of this fired product film (transparent conductive film) is 100 g / c
It was m ² . The specific surface area is measured using a BET surface area measuring device (Multisorb 12 manufactured by Mitsuwa Rikagaku Kogyo).
It was carried out by a method of adsorbing nitrogen gas at a liquid nitrogen temperature.

Then, the above substrate was immersed in a 0.02 M solution of 1,1'-ferrocene dicarboxylic acid in methanol as an oxidation-reduction substance, subjected to adsorption treatment, and dried at room temperature to prepare a ferrocene-bonded electrode.

Using the ferrocene-bonded electrode thus obtained and the dye-bonded electrode of Example 1 as an electrode paired with the ferrocene-bonded electrode, an EC dye structural unit was assembled by contacting with an electrolyte solution. In this case, for the dye-bonded electrode, the structural unit that produced three different hues shown in Example 1 was prepared, and the distance between both electrodes was 0.5 mm.

As the electrolyte solution, a 0.2 M solution of tetrabutylammonium perchlorate in propylene carbonate was used. The size of the pair of electrodes produced was 5 mm × 5 mm.

A display device was manufactured by stacking three of the above structural units and connecting each pair of electrodes with a lead wire (a dye binding electrode for the anode and a ferrocene binding electrode for the cathode).

In this display device, when a voltage of 3 V was applied to the magenta color-forming structural unit at room temperature, the styryl derivative was oxidized at the anode and changed from colorless to magenta. Next, when a voltage of 3 V was applied to the cyan color-forming structural unit at room temperature, the styryl derivative was oxidized at the anode and changed from colorless to cyan. When a voltage of 3 V was applied to the yellow color forming structural unit at room temperature, the styryl derivative was oxidized at the anode,
Colorless changed to yellow. It should be noted that, in the above-mentioned color-developing household, the ferrocene derivative of the counter electrode also causes a redox reaction, but since the oxidant and the reductant are colorless, it does not affect the color observed as a whole.

Furthermore, when a voltage of 3 V was simultaneously applied to the magenta color-forming structural unit and the cyan color-forming structural unit at room temperature, the styryl derivative was oxidized at the anodes of the respective structural units to form magenta and cyan colors, and as a whole. It changed from colorless to blue. Next, when a voltage of 3 V was applied simultaneously to the magenta color-forming structural unit and the yellow color-forming structural unit at room temperature, the styryl derivative was oxidized at the anodes of the respective structural units to form magenta and yellow, and the overall colorless to It turned red. When a voltage of 3 V was simultaneously applied to the cyan color-forming structural unit and the yellow color-forming structural unit at room temperature, the styryl derivative was oxidized at the anodes of the respective structural units to form cyan and yellow colors, and overall colorless to green. Changed to.

Furthermore, when a voltage of 3 V was simultaneously applied to the three color-forming structural units at room temperature, the styryl derivative was oxidized at the anode of each structural unit to develop magenta, cyan, and yellow, and the overall colorless to It turned black.

The response speed until reaching the ultimate transmittance was 80 msec in all cases. Even when the application of voltage was stopped, color development continued for 600 seconds or longer. Further, even when the color development-color erasing was repeated 10,000 times, the color strength during color development and the transparency during color erasure hardly changed.

[0181]

According to the present invention, the above-mentioned problems in the prior art can be solved, full-color can be easily realized, the memory property is excellent, and the response speed, the coloring efficiency and the repeating durability are greatly improved. Can be provided.

[Brief description of drawings]

FIG. 1 is a schematic explanatory view showing an example of an EC device of the present invention.

FIG. 2 is a partially enlarged view of a region X in FIG.

FIG. 3 is a schematic explanatory view showing an example of an EC device of the present invention.

FIG. 4 is a partially enlarged view of a region X in FIG.

[Explanation of symbols]

10 Transparent electrode 12 Transparent electrode 20 Semiconductor nanoporous layer 22 Semiconductor nanoporous layer 25 EC dye 30 Electrolyte layer 40 structural units 50 power 60 lead wire

Claims (17)

[Claims] 1. An electrochemical oxidation reaction and reduction reaction while a pair of transparent electrodes having a semiconductor nanoporous layer formed on at least one surface are arranged so that the semiconductor nanoporous layers face each other. An electrochromic device comprising a plurality of laminated structural units sandwiching an electrolyte layer containing an electrochromic dye that reversibly develops or erases color by at least one of the above. 2. A pair of transparent electrodes having, on at least one surface thereof, a semiconductor nanoporous layer carrying an electrochromic dye capable of reversibly developing or erasing color by at least one of electrochemical oxidation reaction and reduction reaction. An electrochromic device comprising: a plurality of structural units having an electrolyte layer sandwiched between the semiconductor nanoporous layers so that the semiconductor nanoporous layers face each other. 3. The electrochromic device according to claim 1, wherein 2 to 4 of the structural units are laminated. 4. The electrochromic device according to claim 2, wherein a different electrochromic dye is carried for each structural unit. 5. The electrochromic device according to claim 1, wherein at least one of the semiconductor nanoporous layers has a multilayer structure. 6. The electrochromic device of claim 5, wherein both semiconductor nanoporous layers are multi-layered structures. 7. The electrochromic device according to claim 5, wherein the semiconductor nanoporous layer is laminated by low temperature firing at 150 to 200 ° C. 8. The electrochromic device according to claim 5, wherein a different electrochromic dye is carried in each layer of the semiconductor nanoporous layer having a multilayer structure. 9. The electrochromic device according to claim 1, further comprising a charge transfer agent contained in the electrolyte layer. 10. The electrochromic device according to claim 2, wherein a charge transfer agent is supported on the semiconductor nanoporous layer. 11. The semiconductor fine particles contained in the semiconductor nanoporous layer are a single semiconductor, an oxide semiconductor, a compound semiconductor,
The electrochromic device according to claim 1, which is selected from an organic semiconductor, a complex oxide semiconductor, and a mixture thereof. 12. The composite oxide semiconductor is SnO._Two-Z
nO, Nb_TwoO₅-SrTiO_Three, Nb_TwoO₅-Ta_Two
O₅, Nb_TwoO₅-ZrO_Two, Nb_TwoO₅-TiO_Two,
Ti-SnO_Two, Zr-SnO_Two, In-SnO_Twoas well as
Bi-SnO _TwoThe elect according to claim 11, which is selected from
Trochromic device. 13. The electrochromic device according to claim 2, wherein a heat treatment is performed before the electrochromic dye is supported on the semiconductor nanoporous layer. 14. The semiconductor nanoporous layer has a thickness of 100 μm.
The electrochromic device according to claim 1, wherein the electrochromic device has a thickness of m or less. 15. The electrochromic device according to claim 1, wherein the electrochromic dye is selected from organic compounds and metal complexes. 16. A full color image is formed by any one of an area gradation method by level ground mixing, a density gradation method by level ground mixing, an area gradation method by layer mixing and a density gradation method by layer mixing. The electrochromic device according to any one of 1 to 15. 17. The response speed until reaching the ultimate transmittance or the ultimate absorbance is 100 msec or less.
The electrochromic device according to any one of 6 above.