JP2006256954A - Prussian blue-type metal complex ultrafine particle, and its dispersion liquid, and manufacturing method thereof - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a simple and easy method for manufacturing Prussian blue-type metal complex ultrafine particles in large amounts with a high yield, and to provide the Prussian blue-type metal complex ultrafine particles which are excellent in dispersion stability in various kinds of solvents and suitable for industrial application and practical utilization, and its manufacturing method. <P>SOLUTION: The method for manufacturing the Prussian blue-type metal complex ultrafine particles comprises the steps of: (A) mixing an aqueous solution containing an anionic metal-cyano complex the central metal of which is a metal atom M<SB>1</SB>with an aqueous solution containing metal cations of a metal atom M<SB>2</SB>, and depositing crystals of the Prussian blue-type metal complex having the metal atom M<SB>1</SB>and the metal atom M<SB>2</SB>; (B) preparing a dispersion liquid of the Prussian blue-type metal complex ultrafine particles by mixing a solution consisting of a ligand L dissolved in a solvent with the crystals of the Prussian blue-type metal complex; and (C) forming the Prussian blue-type metal complex separated from the dispersion liquid as ultrafine particles of a nanometer size. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to Prussian blue-type metal complex ultrafine particles, a dispersion thereof, and a method for producing them, and more particularly to nanometer-size Prussian blue-type metal complex ultrafine particles, a dispersion thereof, and a method for producing them.

  A complex compound composed of a specific metal and a specific molecule can have various physical properties by a combination of the metal species and coordination molecular species. And its application range is wide, and it is used in various fields such as pharmaceuticals, luminescent materials and paints.

  On the other hand, solid micronization is not limited to simply miniaturizing bulk solids, but may exhibit unique physical properties that can be expressed only in microparticles. Yes. For example, the color of semiconductors and metal fine particles varies depending on the particle size. The various colors of stained glass make use of these properties of ultrafine metal particles. Magnetic oxide fine particles such as ferrite have already been put into practical use for DNA analysis and the like. However, with regard to micronization of metal complexes, several studies have been announced over the past few years and are still in its infancy.

Among the metal complexes, Prussian blue and its similar compounds (Prussian blue type metal complexes) have been subjected to many studies and practical applications. For example, Prussian blue itself has long been used as a blue paint. Furthermore, application studies for displays and biosensors are also progressing, and some of them have already been commercialized. The crystal structure of the Prussian blue-type metal complex is shown in FIG. 10 (in the present invention, the Prussian blue-type metal complex crystal is based on the Prussian blue crystal structure and includes substitution of transition metals, presence of defects, various ions in the voids. , Including water intruded). More specifically, the structure between two kinds of metal atoms M ₁ and metal atoms M ₂ (metal atom 101, metal atom 104) in an NaCl type lattice is formed by a cyano group consisting of carbon atom 102 and nitrogen atom 103. It has a three-dimensionally cross-linked structure. As the metal atom M ₁ or M ₂ , a very wide range of metals such as vanadium, chromium, molybdenum, tungsten, manganese, iron, ruthenium, cobalt, nickel, platinum, and copper can be used. It is known that physical properties such as magnetism and photoresponsiveness can be changed by changing the metal species, and various substances have been studied (see Patent Document 1 and Patent Document 2).

In order to make the Prussian blue-type metal complex into ultrafine particles in a stable state, it is necessary to improve dispersibility in a solvent. If high dispersion stability can be obtained with various solvents, an inexpensive and simple film forming method such as spin coating can be adopted, and application to various product fields such as biosensors becomes possible.
That is, when considering the practical application of Prussian blue type metal complex, how to make fine particles becomes a problem. In recent years, several proposals have been made on the method for producing fine particles of Prussian blue type metal complex. However, in order to stabilize the fine particles, for example, as a stabilizing molecule, a surfactant such as AOT (di-2-ethylhexylsulfosuccinate sodium salt) (used in the reverse micelle method), a high PVP (polyvinylpyrrolidone), etc. Some use proteins such as molecules and ferritin (see Non-Patent Document 1, etc.), but the process of synthesizing ultrafine particles is complicated, and both require expensive materials and a large amount of organic solvent, and are low in cost. And not suitable for simple mass production.
(Refer nonpatent literature 1).
Japanese Patent Laid-Open No. 2005-3679 Japanese Patent Publication No. 7-270831 M.M. Yamada et al., "Journal of the American Chemical Society (J. Am. Chem. Soc)", 126 (2004) pp. 9482-9443

In this regard, in the fine particle synthesis method such as the reverse micelle method, the number of molecules that protect the surface of the fine particle is limited. Here, as the reverse micelle method, for example, (i) a first step of preparing a first reverse micelle solution containing a metal cyano complex (anion) and a second reverse micelle solution containing a metal cation, respectively (ii) The second step of mixing the first reverse micelle solution and the second reverse micelle solution, and (iii) adding a molecule for protecting the surface (surface protective molecule) to the mixed liquid obtained in the second step It is a method of synthesis. In the case of the reverse micelle method, a large amount of a surfactant constituting the reverse micelle must be prepared in addition to the surface protecting molecule, and a large amount of organic solvent is required, resulting in an increase in cost. Furthermore, since the types (combinations) of solvents, surfactants, and surface protective molecules that can stably form reverse micelles are limited, this method is poor in versatility.
Therefore, the present invention aims to provide a method capable of producing Prussian blue-type metal complex ultrafine particles simply, in large quantities, and efficiently, and further has excellent dispersion stability in various solvents and is industrially utilized. It is another object of the present invention to provide Prussian blue-type metal complex ultrafine particles suitable for practical use, dispersions thereof, and production methods thereof.

The above problems have been achieved by the following means.
(1) (A) An aqueous solution containing an anionic metal cyano complex having a metal atom M ₁ as a central metal and an aqueous solution containing a metal cation of the metal atom M ₂ are mixed, and the metal atom M ₁ and the metal A Prussian blue-type metal complex crystal having an atom M ₂ is precipitated, and then (B) a solution in which the ligand L is dissolved in a solvent and the Prussian blue-type metal complex crystal are mixed, and Prussian blue And (C) a Prussian blue-type metal complex ultrafine particle, wherein the Prussian blue-type metal complex is formed as a nanometer-sized ultrafine particle by separating from the dispersion liquid. .
(2) (A) An aqueous solution containing an anionic metal cyano complex having the metal atom M ₁ as a central metal and an aqueous solution of a metal cation of the metal atom M ₂ are mixed, and the metal atom M ₁ and the metal atom M are mixed. A Prussian blue-type metal complex crystal having ₂ and then (B1) an organic solution in which the ligand L is dissolved in an organic solvent and the Prussian blue-type metal complex crystal are mixed to obtain a Prussian blue type A dispersion of metal complex ultrafine particles is obtained, and (C) by removing the solvent from the dispersion, solid powdery Prussian blue-type metal complex ultrafine particles having an average particle diameter of 50 nm or less are obtained as an aggregate. (1) The method for producing the Prussian blue-type metal complex ultrafine particles according to (1).
(3) The method for producing Prussian blue-type metal complex ultrafine particles according to (2), wherein water is contained in an organic solvent solution in which the ligand L is dissolved.
(4) (A) An aqueous solution containing an anionic metal cyano complex having the metal atom M ₁ as a central metal and an aqueous solution containing a metal cation of the metal atom M ₂ are mixed, and the metal atom M ₁ and the metal are mixed. to precipitate crystals of Prussian blue-type metal complex having atoms M _2, then a solution prepared by dissolving in a solvent comprising a (B2) the Prussian blue-type metal complex crystals, the ligand L of water-soluble alcohols or water To obtain a dispersion of Prussian blue-type metal complex ultrafine particles, and (C) by removing the solvent from the dispersion, solid Prussian blue-type metal complex ultrafine particles having an average particle diameter of 50 nm or less are obtained. The method for producing Prussian blue-type metal complex ultrafine particles according to (1), which is obtained as an aggregate.
(5) a metal atom _{M 1} is, vanadium, chromium, molybdenum, tungsten, manganese, iron, ruthenium, cobalt, nickel, platinum, and at least one selected from copper, the metal atom _{M 2} is vanadium, chromium, manganese , Iron, ruthenium, cobalt, rhodium, nickel, palladium, platinum, copper, silver, zinc, lanthanum, europium, gadolinium, lutetium, barium, strontium, and calcium, and the ligand L is The Prussian blue-type metal as described in any one of (1) to (4), which is one or more of the compounds represented by any one of the general formulas (1) to (3) A method for producing complex ultrafine particles.

(In the formula, R ₁ and R ₂ each independently represent a hydrogen atom or an alkyl group having 8 or more carbon atoms. However, an unsaturated bond may be introduced into these groups.)

(In the formula, R ₃ represents an alkyl group having 8 or more carbon atoms. However, an unsaturated bond may be introduced into this group.)

(In the formula, R ₄ represents an alkyl group having 6 or more carbon atoms, and R ₅ represents an alkyl group. However, an unsaturated bond may be introduced into these groups.)
(6) Obtaining Prussian blue-type metal complex ultrafine particles having a desired composition by adjusting the mixing amount of the two or more metal ions, wherein the metal atom M ₁ or M ₂ is two or more metal atoms. The method for producing Prussian blue-type metal complex ultrafine particles according to any one of (1) to (5).
(7) (A) A Prussian blue-type metal complex crystal is precipitated, and (B) an optical property modifier is added in preparing the dispersion of the ultrafine particles. The method for producing the Prussian blue-type metal complex ultrafine particles according to any one of the above.
(8) (A) An aqueous solution containing an anionic metal cyano complex having the metal atom M ₁ as a central metal and an aqueous solution containing a metal cation of the metal atom M ₂ are mixed, and the metal atom M ₁ and the metal are mixed. A Prussian blue-type metal complex crystal having an atom M ₂ is precipitated, and then (B) a solution in which the ligand L is dissolved in a solvent is mixed with the Prussian blue-type metal complex crystal to obtain a nanometer. A method for producing a dispersion of Prussian blue-type metal complex ultrafine particles, characterized by using a dispersion of Prussian blue-type metal complex ultrafine particles of a size.
(9) metal atom M ₁ of Prussian blue-type metal complex crystals and a metal atom M ₁ and metal atom M ₂ is vanadium, chromium, molybdenum, tungsten, manganese, iron, ruthenium, cobalt, nickel, platinum, and copper at least one, and the vanadium metal atom M _2, chromium, manganese, iron, ruthenium, cobalt, rhodium, nickel, palladium, platinum, copper, silver, zinc, lanthanum, europium, gadolinium, lutetium, barium selected from, An average particle diameter of 50 nm, which is at least one selected from strontium and calcium and in which one or more of the compounds represented by any one of the following general formulas (1) to (3) are coordinated to the crystal Prussian blue-type metal complex ultrafine particles characterized by being the following ultrafine particles.

(In the formula, R ₁ and R ₂ each independently represents a hydrogen atom or an alkenyl group having 8 or more carbon atoms.)

(In the formula, R ₃ represents an alkenyl group having 8 or more carbon atoms.)

(In the formula, R ₄ represents an alkenyl group having 6 or more carbon atoms, and R ₅ represents an alkyl group or an alkenyl group.)

  According to the Prussian blue-type metal complex ultrafine particles and the method for producing the dispersion thereof according to the present invention, Prussian blue-type metal complex ultrafine particles having excellent dispersion stability can be produced easily and in large quantities. Therefore, Prussian blue-type metal complex ultrafine particles can be produced with high yield and high purity without the need for such a solvent or an expensive solvent. Further, the Prussian blue-type metal complex ultrafine particles of the present invention and the dispersions thereof have high dispersion stability in various solvents, and have an excellent effect of being able to meet practical demands in a wide range of fields.

Hereinafter, the Prussian blue-type metal complex ultrafine particles of the present invention and the production method thereof will be described in detail.
In the method for producing the Prussian blue type metal complex ultrafine particles of the present invention, an aqueous solution containing an anionic metal cyano complex having a metal atom M ₁ as a central metal and an aqueous solution containing a metal cation of a metal atom M ₂ are used. It is done. The metal atom _{M 1} is vanadium (V), chromium (Cr), molybdenum (Mo), tungsten (W), manganese (Mn), iron (Fe), ruthenium (Ru), cobalt (Co), nickel (Ni ), Platinum (Pt), copper (Cu), and the like. As the metal atom _{M 2} is vanadium (V), chromium (Cr), manganese (Mn), iron (Fe), ruthenium (Ru), cobalt (Co), rhodium (Rh), nickel (Ni), palladium (Pd) , Platinum (Pt), copper (Cu), silver (Ag), zinc (Zn), lanthanum (La), europium (Eu), gadolinium (Gd), lutetium (Lu), barium (Ba), strontium (Sr) And calcium (Ca). Iron, chromium, cobalt preferably among them as the metal atom M _1, particularly preferably iron, iron metal atom M ₂ is comprised of cobalt, nickel, vanadium, copper, manganese, zinc is preferred, iron, cobalt, nickel and more preferably .

But not limited counterion especially a metal atom M ₁ in anionic metal-cyano aqueous solution of a complex of a central metal, potassium ions, ammonium ions, sodium ions, and the like. Although counter ion in an aqueous solution of metal cations the metal atom _{M 2} is not particularly _limited, ^NO 3 _{-, SO} ^{4 2-,} and the like.

Two or more metals may be combined as the metal atom M ₁ or M ₂ . Regarding the combination of two kinds of metals, the metal atom M ₁ is preferably a combination of iron and chromium, a combination of iron and cobalt, a combination of chromium and cobalt, and more preferably a combination of iron and chromium. For the metal atom M _2, a combination of iron and nickel, a combination of iron and cobalt, preferably a combination of nickel and cobalt, a combination of iron and nickel is more preferable.
At this time, the physical properties of the obtained Prussian blue-type metal complex ultrafine particles can be controlled by adjusting the composition of the combined metals (preferably, the optical properties can be controlled).

In the method for producing Prussian blue-type metal complex ultrafine particles of the present invention, a solution in which the ligand L is dissolved in a solvent is used. The solvent is preferably determined in combination with the ligand L. That is, it is preferable to select one that sufficiently dissolves the ligand L in the solvent. When an organic solvent is used as the solvent, toluene, dichloromethane, chloroform, hexane, ether and the like are preferable.
When using a ligand that dissolves in water, such as 2-aminoethanol, water can be used as a solvent, and water-dispersible Prussian blue-type metal complex ultrafine particles can also be obtained. At this time, it is also preferable to use alcohol as a solvent.

  In the present invention, the Prussian blue-type metal complex ultrafine particle dispersion is produced in a process including the following (A) and (B), and the fine particles are obtained in a process including the following (A) to (C). Further, as a preferred embodiment, when producing the organic solvent-dispersed ultrafine particles, the step (B) is designated as the step (B1), and when producing the water-dispersed ultrafine particles, the step (B) is designated as the step (B2). And Hereinafter, each process will be described in detail.

In the step (A), an aqueous solution containing a metal cyano complex (anion) having the metal atom M ₁ as a central metal and an aqueous solution containing a metal cation of the metal atom M ₂ are mixed, and the metal atom M ₁ and a step of precipitating crystals of Prussian blue-type metal complex having a metal atom M _2. At this time, the mixing ratio of the metal cyano complex and the metal cation is not particularly limited, but the mixing is preferably performed so that the molar ratio of “M ₁ : M ₂ ” is 1: 1 to 1: 1.5.

Step (B) is a step of mixing a solution in which ligand L is dissolved in a solvent and the Prussian blue-type metal complex crystal prepared in step (A). Although the amount of the solvent used at this time is not particularly limited, for example, it is preferable that “ligand L: solvent” is 1: 5 to 1:50 by mass ratio. Moreover, it is preferable to stir when mixing, whereby a dispersion in which the ultrafine particles of Prussian blue type metal complex are sufficiently dispersed in an organic solvent is obtained.
The addition amount of the ligand L is expressed by a molar ratio of “(M) with respect to metal ions (total amount of metal atoms M ₁ and M ₂ ) contained in the microcrystal of the Prussian blue-type metal complex prepared in the step (A). ₁ + _M 2): L "is 1: 0.2 to 1: is preferably 2.

  Step (B1) is a step of mixing an organic solution in which the ligand L is dissolved in an organic solvent and the Prussian blue-type metal complex crystal prepared in step (A). In addition, it is preferable to add water in this process at the point which can raise the production | generation speed | rate of a Prussian blue type metal complex ultrafine particle, The addition amount is "solvent: water" 1: 0.01-1 by mass ratio. : It is preferable that it is 0.1.

In step (B2), a solution in which the water-soluble ligand L is dissolved in an alcohol (an alcohol includes lower alcohols such as methanol, ethanol, propanol, etc., preferably methanol) or water, In this step, the Prussian blue-type metal complex crystal prepared in the step (A) is mixed.
Here, when water is added to the solid material obtained after the alcohol separation, an aqueous dispersion in which ultrafine particles of Prussian blue-type metal complex are dispersed in water can be obtained. Alternatively, the Prussian blue-type metal complex crystal prepared in the step (A) is directly added to the ligand L aqueous solution and stirred to obtain a dispersion in which the ultrafine particles of the Prussian blue-type metal complex are dispersed in water. be able to. However, it is preferable to use an alcohol solvent from the viewpoint of stability and yield of the obtained Prussian blue-type metal complex ultrafine particles.

  Step (C) is a step of separating Prussian blue from the solvent. For example, when the ultrafine particles of Prussian blue type metal complex are dispersed in the solvent, the solvent can be distilled off under reduced pressure to separate the dispersion. The solvent may be removed by filtration or centrifugation as an untreated state. At this time, when the mixed solution is obtained through the step (B1), the solid powder of the ultrafine particle aggregate is obtained by removing the organic solvent. When a mixed solution is obtained through the step (B2), a solvent composed of alcohol or water is removed and separated to obtain a water-dispersible ultrafine particle aggregate as a solid powder.

In addition, in the method for producing Prussian blue-type metal complex ultrafine particles of the present invention, an additive may be added in addition, and different physical properties can be imparted to the Prussian blue-type metal complex ultrafine particles by the action of the additive. For example, it is preferable to add ammonia, pyridine, a combination thereof, or the like as an optical property modifier during the production of Prussian blue-type metal complex ultrafine particles, and to control the optical properties of the product by the presence or absence and amount of the addition. . At this time, it is preferable to add an optical property adjusting agent in the step (A). The addition amount of the optical characteristics preparations is not particularly limited, the metal atom M _2, is preferably added so as to be 10 to 200 percent by mole ratio.

Furthermore, as described above, a plurality of kinds of metals can be used in combination as the metal atom M ₁ or M ₂ , but the physical properties of Prussian blue type metal complex ultrafine particles can be adjusted by adjusting the composition of the metal. Can be controlled. Specifically, for example, (Fe _1-x Ni _x ) ₃ [Fe (CN) ₆ ] ₂ is used by combining iron and nickel with the metal raw material M ₂ and adjusting its composition (“x” in the formula). It is preferable to control.
At this time, Prussian blue-type metal complex ultrafine particles having the target metal composition can be obtained by adding the raw material compound containing the target metal in the step (A) while changing the mixing ratio.

  In the production method of the present invention, the ligand L is dissolved in a solvent and used. When using an organic solvent such as toluene, those containing a long-chain alkyl group are preferred. Further, as the ligand L, it is preferable to use one or more of those having a pyridyl group or an amino group represented by any one of the following general formulas (1) to (3) as a binding site with the fine particles. .

In general formula (1), R ₁ and R ₂ each independently represent a hydrogen atom or an alkyl group having 8 or more carbon atoms, and the alkyl group is not particularly limited, but has 12 to 18 carbon atoms. It is preferable that When R ₁ and R ₂ are alkyl groups, a carbon-carbon unsaturated bond may be introduced, and at least one unsaturated bond is preferably contained, and although there is no upper limit, 2 unsaturated bonds are contained. The following is preferable. By using the ligand L having an alkenyl group containing a carbon-carbon unsaturated bond, for example, in a fine particle of a ligand not containing it, a polar solvent (methanol or acetone in which the ligand may be eliminated) is used. Even when it is difficult to disperse in a solvent other than, for example, chloroform), the dispersibility can be improved. Specifically, by using a ligand having an unsaturated bond, it can be well dispersed in a nonpolar solvent (for example, hexane) unless the ligand is eliminated. The same applies to R ₃ and R ₄ .
Among the compounds represented by the general formula (1), 4-di-octadecylaminopyridine, 4-octadecylaminopyridine and the like are preferable.

In the general formula (2), R ₃ represents an alkyl group having 8 or more carbon atoms, and is not particularly limited, but preferably has 12 to 18 carbon atoms. R ₃ may have a carbon-carbon unsaturated bond introduced therein, preferably contains at least one unsaturated bond, and has no upper limit, but preferably contains 2 or less unsaturated bonds. . Among the compounds represented by the general formula (2), oleylamine, stearylamine and the like are preferable.

In General Formula (3), R ₄ is an alkyl group having 6 or more carbon atoms, and preferably has 12 to 18 carbon atoms. R ₅ is an alkyl group and preferably has 1 to 60 carbon atoms. However, a carbon-carbon unsaturated bond may be introduced into R ₄ and R ₅ . R ₄ and R ₅ preferably contain at least one unsaturated bond, and there is no particular upper limit, but the number of unsaturated bonds contained is preferably 2 or less.
In addition, the compound represented by any one of the general formulas (1) to (3) may have a substituent as long as the effect of the present invention is not hindered.

  The Prussian blue-type metal complex ultrafine particles of the present invention can be redispersed in various solvents (organic solvent, water, etc.), and an ultrafine particle dispersion having a target concentration can be prepared. In addition, a solvent different from the solvent used for the fine particle preparation can be used as a solvent for redispersion, and can be contained in a target type solvent at a target concentration according to the application.

By the production method of the present invention, nanometer-size Prussian blue-type metal complex ultrafine particles can be obtained. FIG. 1 is an explanatory view schematically showing the structure of the Prussian blue-type metal complex ultrafine particles. In this ultrafine particle, Prussian blue-type metal complex fine particle crystal 1 has a crystal structure as shown in FIG. 10, and has a structure in which ligand L (2) is coordinated on the crystal particle surface. ing. At this time, the amount of the ligand L is not particularly limited, and depends on the particle diameter and particle shape of the ultrafine particles, but for example, metal atoms (metal atoms M ₁ and M _{2 in} the Prussian blue type metal complex crystal). The molar ratio is preferably about 5 to 30% with respect to the total amount).
However, the Prussian blue-type metal complex 1 may have defects and vacancies in its crystal lattice. For example, vacancies may be inserted at the positions of iron atoms, and cyano groups around them may be substituted with water. It is also preferable to control the optical characteristics by adjusting the amount and arrangement of such holes.

  The particle size of the Prussian blue-type metal complex ultrafine particles is not particularly limited, but is preferably miniaturized to the nanometer order in terms of obtaining a nanosize effect, and more preferably an average particle size of 50 nm or less. In view of improvement in dispersibility in a solvent, the average particle diameter is particularly preferably 20 nm (in the present invention, the particle diameter means an equivalent circle diameter unless otherwise specified, and an image of ultrafine particles obtained by observation with an electron microscope). More specifically, the average particle diameter is calculated as described above by measuring the particle diameter of at least 30 ultrafine particles as described above, unless otherwise specified. The average particle size was obtained, or the average particle size of the particles was estimated from the half-value width of the signal from the powder X-ray diffraction (XRD) measurement of the ultrafine powder. It is also possible.).

The Prussian blue-type metal complex obtained by the production method of the present invention exhibits excellent dispersion stability in various solvents (in the present invention, “solvent” is used to mean “dispersion medium”) (for example, It is possible to maintain a stable dispersion state even after several months.) By applying a thin film, it can be applied in a wide range of fields such as displays using electrochemical characteristics, photochromic elements, biosensors, and electrochromic elements. (In this respect, what is described in Non-Patent Document 1 is based on the reverse micelle method, and the solvent that can be used is limited, and physical properties such as optical properties are not specified.)
According to the production method of the present invention, the optical properties of the Prussian blue-type metal complex ultrafine particles can be further controlled, and various color materials can be obtained by adjusting subtle colors. When used in a non-light emitting color display, it can be color materials corresponding to cyan, yellow, and magenta. When used in a light emitting color display, color materials corresponding to R, G, and B are used. You can also.
When the dispersion liquid is used for the Prussian blue-type metal complex ultrafine particles of the present invention, an inexpensive film forming method such as spin coating can be used, so that the device manufacturing cost can be improved. In addition, the thin film using the Prussian blue-type metal complex ultrafine particles of the present invention has large voids between the fine particles, so that the ion conductivity is improved and the target molecule can be easily penetrated into the thin film in sensing. Improvement in chemical sensitivity and response speed is expected. Moreover, according to the method for producing the Prussian blue-type metal complex ultrafine particles of the present invention, it is possible to carry out mass synthesis, which has been difficult in the past, with a simple process and at low cost.

  EXAMPLES The present invention will be described in more detail below with reference to examples, but the present invention is not limited thereto.

Example 1
_{(NH 4)} 4 to ^[Fe II _(CN) 6] solution and ^Fe III _{(NO 3)} that the 1.0g was dissolved in water ₃ · 9H 2 O 1.4g were mixed aqueous solution prepared by dissolving in water, Prussian blue ( Fe ^III ₄ [Fe ^II (CN) ₆ ] ₃ ) crystallites were precipitated (including those containing ammonium ions). Centrifugation separated Prussian blue microcrystals that were insoluble in water, which were washed three times with water and then twice with methanol and dried under reduced pressure.
The result of analyzing the bulk body of the produced Prussian blue crystal with a powder X-ray diffractometer is shown by a curve 21 in FIG. This coincided with that of Prussian blue (Fe ₄ [Fe (CN) ₆ ] ₃ ) retrieved from the standard sample database (FIG. 2 (I)). In the FT-IR measurement, a peak due to Fe—CN stretching vibration appears in the vicinity of 2070 cm ⁻¹ (see curve 31 in FIG. 3), indicating that this solid is Prussian blue.

As ligand L, 0.5 ml of water was added to 5 ml of a toluene solution in which 0.17 g of oleylamine containing a long-chain alkyl group was dissolved. A bulk body of 0.2 g of Prussian blue crystals (Fe ^III ₄ [Fe ^II (CN) ₆ ] ₃ ) synthesized earlier was further added. After stirring for one day, all the microcrystals of Fe ^III ₄ [Fe ^II (CN) ₆ ] ₃ were dispersed in the toluene layer to obtain Prussian blue ultrafine particles of the present invention in a dark blue dispersion. The result of the FT-IR measurement at this time is shown by a curve 33 in FIG.

Further, the water and toluene layers were separated, and the dark blue toluene solution was filtered to obtain a dispersion.
The ultraviolet-visible absorption spectrum measurement result of this dispersion is shown by a curve 41 in FIG. The peak around 680 nm is known as Prussian blue Fe-Fe charge transfer absorption, and it can be seen that this fine particle dispersion contains Prussian blue. Moreover, the result of having observed this dispersion liquid with the transmission electron microscope is shown in FIG. From this, it was confirmed that ultrafine particles having a particle diameter of about 10 to 15 nm were synthesized.
The bulk body of Fe ^III ₄ [Fe ^II (CN) ₆ ] ₃ obtained in this way does not remain in water but can be almost entirely extracted as ultrafine particles in the toluene layer.

Toluene was distilled off under reduced pressure from the dispersion of Prussian blue ultrafine particles obtained above to separate the ultrafine particles from the solvent. At this time, Prussian blue ultrafine particles were obtained almost quantitatively as a solid powder of the aggregate.
The obtained Prussian blue ultrafine particles are easily redispersed in an organic solvent such as dichloromethane, chloroform, and toluene to form a deep blue transparent solution.
As a result of analyzing the obtained Prussian blue ultrafine particle solid powder with a powder X-ray diffractometer, it coincided with the Prussian blue peak position contained in the standard sample database (see curve 23 in FIG. 2 (II)). The low-angle peak is a broad background due to excessive oleylamine.

(Example 2)
Prussian blue microcrystals were obtained by the procedure described in Example 1.
As a ligand L, 0.2 g of a bulk form of the above microcrystal (Fe ^III ₄ [Fe ^II (CN) ₆ ] ₃ ) was added to 5 ml of a methanol solution in which 0.040 g of 2-aminoethanol was dissolved. The Prussian blue ultrafine particles of the present invention were obtained by stirring to a certain degree. Even after stirring, the Prussian blue ultrafine particles existed as a solid without dissolving in methanol. The result of the FT-IR measurement at this time is shown by a curve 32 in FIG.

From this, methanol was removed to obtain Prussian blue ultrafine particles (Fe ^III ₄ [Fe ^II (CN) ₆ ] ₃ ) (solid powder sample α). When water was added to the solid powder sample α, all were dispersed to form a deep blue transparent aqueous dispersion (dispersion sample β).
The result of observation of the obtained dispersion liquid sample β with a transmission electron microscope is shown in FIG. From this, it was confirmed that ultrafine particles having a particle diameter of about 10 to 15 nm were synthesized. Also in the UV-visible absorption spectrum measurement of this dispersion, a Prussian blue peak at 680 nm was observed (curve 42 in FIG. 4) as in the case of the organic solvent ultrafine particle dispersion (curve 41 in FIG. 4). reference). From these measurements, it can be seen that a stable aqueous dispersion of Prussian blue ultrafine particles was obtained.
The Prussian blue signal was confirmed from the result of analyzing the solid powder sample α by the powder X-ray diffractometer (see the curve 22 in FIG. 2 (II)). As a result of analysis from the half-value width of each signal, it was found that the average particle diameter of the crystal was about 10 nm to 20 nm. From this, it was found that the solid powder sample α was an aggregate of Prussian blue ultrafine particles. The solid powder sample α can also be obtained by drying the above dispersion sample β under reduced pressure to remove water.

(Example 3)
To 1.5 ml of an aqueous solution of potassium ferricyanate, K ₃ [Fe (CN) ₆ ] 0.3289 g (0.9990 mmol), 0.1 ml of aqueous ammonia NH ₃ (28.00%, 14.76N) was added, and 1.0 ml of an aqueous solution of 0.4369 g (1.501 mmol) of cobalt nitrate Co (NO ₃ ) ₂ .6H ₂ O was added and stirred for about 3 minutes. Thereafter, the Prussian blue-type metal complex crystal was obtained as a red precipitate by centrifugation, and washed with water three times and with methanol once. The yield was 0.6308 g, and the yield was 105.1% (over 100% is considered to be an error due to insufficient drying and containing water).
3.0 ml of a toluene solution of 0.4433 g (1.657 mmol, 100% of the total metal amount (molar ratio)) of oleylamine was added to the coagulation of the Prussian blue-type metal complex crystal (cobalt iron cyano complex crystal) obtained in the previous synthesis. The solution was added to 0.5 ml of a 0.2040 g (0.3396 mmol) aqueous solution and stirred for about 1 day. Thus, Prussian blue-type metal complex ultrafine particles of the present invention were obtained in the dispersion. A dispersion sample γ was obtained under the condition of adding ammonia.

Next, the Prussian blue-type metal complex ultrafine particles were separated and obtained as an agglomerated solid by removing the toluene in the dispersion sample γ by drying under reduced pressure.
The dispersion sample γ was centrifuged, a part of the supernatant was taken out, diluted with toluene, and UV-vis optical measurement was performed. The absorption maximum in the visible region of this sample exists at 480 nm (see FIG. 8), which is different from the maximum position 520 nm obtained without adding ammonia. This change was such that it could be visually discriminated. Those without the addition of ammonia were purplish, but those obtained with the addition of ammonia had an increased red color.
From this result, it can be seen that by adding ammonia, the optical spectrum of the obtained Prussian blue-type metal complex ultrafine particles can be changed, and the optical characteristics can be controlled.

Example 4
(Synthesis of (Fe _0.2 Ni _0.8 ) ₃ [Fe (CN) ₆ ] ₂ )
An aqueous solution (2 ml) of K ₃ [Fe (CN) ₆ ] (0.658 g (2.00 × 10 ⁻³ mol)) was added to FeSO ₄ .7H ₂ O (0.167 g (6.00 × 10 ⁻⁴ mol)). )) And an aqueous solution (1.6 ml) of Ni (NO ₃ ) ₂ .6H ₂ O (0.698 g (2.40 × 10 ⁻³ mol)) added with stirring. It was. The precipitate was centrifugally washed three times with distilled water, and once centrifugally washed with methanol, and then air-dried to obtain Prussian blue-type metal complex crystals having a target metal composition.

(Synthesis of Fe _0.4 Ni _0.6 ) 3 [Fe (CN) ₆ ] ₂ )
An aqueous solution (2 ml) of K ₃ [Fe (CN) ₆ ] (0.658 g (2.00 × 10 ⁻³ mol)) was added to FeSO ₄ .7H ₂ O (0.334 g (1.20 × 10 ⁻³ mol). )) And an aqueous solution (1.2 ml) of Ni (NO ₃ ) ₂ .6H ₂ O (0.523 g (1.80 × 10 ⁻³ mol)) added with stirring. It was. The precipitate was centrifugally washed three times with distilled water, and once centrifugally washed with methanol and then air-dried to obtain Prussian blue-type metal complex crystals having the target metal composition.

(Synthesis of (Fe _0.6 Ni _0.4 ) ₃ [Fe (CN) ₆ ] ₂ )
An aqueous solution (2 ml) of K ₃ [Fe (CN) ₆ ] (0.658 g (2.00 × 10 ⁻³ mol)) was added to FeSO ₄ .7H ₂ O (0.500 g (1.80 × 10 ⁻³ mol)). )) And an aqueous solution (0.8 ml) of Ni (NO ₃ ) ₂ .6H ₂ O (0.349 g (1.20 × 10 ⁻³ mol)) added with stirring. It was. The precipitate was centrifugally washed three times with distilled water, and once centrifugally washed with methanol and then air-dried to obtain Prussian blue-type metal complex crystals having the target metal composition.

(Synthesis of (Fe _0.8 Ni _0.2 ) ₃ [Fe (CN) ₆ ] ₂ )
An aqueous solution (2 ml) of K ₃ [Fe (CN) ₆ ] (0.658 g (2.00 × 10 ⁻³ mol)) was added to FeSO ₄ .7H ₂ O (0.667 g (2.40 × 10 ⁻³ mol)). ) aqueous solution) and _{(1.6ml) Ni (NO} 3) was added with stirring in a mixed solution of aqueous solution of 2 · 6H 2 O (0.174g ( 5.98 × 10 -4 mol)) (0.4ml) It was. The precipitate was centrifugally washed three times with distilled water, and once centrifugally washed with methanol and then air-dried to obtain Prussian blue-type metal complex crystals having the target metal composition.

0.2 ml of water was added to 0.10 g of the four kinds of (Fe _1-x Ni _x ) ₃ [Fe (CN) ₆ ] ₂ synthesized, and a toluene solution of 0.090 g (3.4 × 10 ⁻⁴ mol) of oleylamine. After mixing with 2 ml and stirring for one day, Prussian blue-type metal complex ultrafine particles of the present invention were obtained in the dispersion.
Centrifugation was performed, the toluene layer was separated, and ultrafine particles having the target metal composition were separated. The absorption spectrum of each of the obtained Prussian blue type metal complex ultrafine particles was measured.
FIG. 9 shows the result. In FIG. 9, curve 91 shows the result of Prussian blue-type metal complex ultrafine particles with x = 0.8 in the above chemical structural formula, curve 92 shows the result of x = 0.6, and curve 93 shows x = 0. .4 results are shown, and curve 94 shows the results for x = 0.2.
From this UV-visible absorption spectrum, it can be seen that the wavelength of the Fe-Fe charge transfer absorption band is systematically shifted to the longer wavelength side depending on the Ni content. In addition, the intensity of the absorption band derived from Fe—CN—Ni is systematically increased in the vicinity of 400 nm. This result indicates that Ni and Fe are uniformly distributed in one nanocrystal (ultrafine particle). If the obtained ultrafine particles (powder) have Ni and Fe non-uniformly distributed in one crystal, or it is Ni ₃ [Fe (CN) ₆ ] _2. And Fe ₄ [Fe (CN) ₆ ] ₃ are simply a mixture of the ultrafine particles of Fe ₄ [Fe (CN) ₆ ] _3, no systematic shift is observed in the wavelength of the above-described Fe-Fe charge transfer absorption band.

(Example 5)
Next, except that the metal atoms M ₁ , M ₂ , ligand L, and solvent were changed as shown in the table below, Samples 1 to 16 were treated in the same manner as in Example 1, and Samples 17 to 19 were treated as in Example 2. Similarly, Prussian blue type metal complex ultrafine particles were obtained. Sample 20 is the one obtained in Example 3, and sample 21 is the one obtained in Example 4. As this result shows, according to the method for producing Prussian blue-type metal complex ultrafine particles of the present invention, various Prussian blue-type metal complex ultrafine particles can be produced.

  In all the production examples in the table, the complex crystals synthesized in the step (A) were almost entirely converted into complex fine particles. That is, the yield of ultrafine particles can be reduced to almost 100% by adjusting the charging ratio so that the material for synthesizing the complex crystal is not excessive or insufficient.

In the step of producing the Prussian blue-type metal complex crystal in the step (A), not only the above-described one but also other raw material compounds can be used. For example, in the case of a Prussian ^{_{blue, (NH 4) 4 [Fe}} II (CN) 6] and is not limited to mixing with _{^{Fe III (NO 3) 3 ·}} 9H 2 O, K 3 [Fe III (CN) 6] 1. Mixing an aqueous solution in which 0 g is dissolved in water and an aqueous solution in which 0.84 g of Fe ^II SO ₄ · 7H ₂ O is dissolved in water, or 1.0 g of Na ₄ [Fe ^II (CN) ₆ ] · 10H ₂ O in water Prussian blue-type metal complex ultrafine particles to obtain the objective as well by dissolving the aqueous and ^Fe III a _{(NO 3) 3 · 9H 2} O 0.83g mixing an aqueous solution dissolved in water. Further, as shown so far, the metal atoms M ₁ and M ₂ are not limited to Fe, and FIG. 7 shows a transmission type of cobalt iron cyano complex ultrafine particles produced from [Fe (CN) ₆ ] ³⁻ and Co ^2+. An electron microscope image is shown.

It is explanatory drawing which shows typically the structure of the Prussian blue type metal complex ultrafine particle of this invention. It is a figure which shows the result of the powder X-ray diffraction of a Prussian blue crystal and its ultrafine particle. It is a figure which shows the FT-IR measurement result of Prussian blue crystal | crystallization and its ultrafine particle. It is an ultraviolet visible absorption spectrum of the toluene dispersion (Example 1) of the Prussian blue ultrafine particles and the water dispersion (Example 2). 4 is a photograph-substituting drawing of a transmission electron microscope image of Prussian blue ultrafine particles in the redispersion liquid (solvent: toluene) obtained in Example 1. 4 is a photograph-substituting drawing of a transmission electron microscope image of Prussian blue ultrafine particles in the aqueous dispersion obtained in Example 2. 6 is a photograph-substituting drawing of a transmission electron microscopic image of cobalt iron cyano complex ultrafine particles in the organic solvent dispersion obtained in Example 6. FIG. 4 is a UV-vis spectrum of ultrafine cobalt iron cyano complex particles (solvent: toluene) obtained in Example 3. The composition of the metal atom M ₂ - is an absorption spectrum with respect to a change in the (iron-nickel composition). It is explanatory drawing which shows typically the crystal structure of a Prussian blue type metal complex.

Explanation of symbols

1 Prussian blue type metal complex (microcrystal)
2 Ligand L
21 X-ray diffraction measurement result of Prussian blue crystal 22 X-ray diffraction measurement result of water-dispersible Prussian blue ultrafine particle 23 X-ray diffraction measurement result of organic solvent-dispersible Prussian blue ultrafine particle 31 Infrared absorption spectrum of Prussian blue crystal 32 Infrared absorption spectrum of water-dispersible Prussian blue ultrafine particles 33 Infrared absorption spectrum of organic solvent-dispersible Prussian blue ultrafine particles 41 Ultraviolet-visible absorption spectrum of Prussian blue ultrafine particles (toluene dispersion) 42 Prussian blue ultrafine particles (aqueous dispersion) ) UV-visible absorption spectrum 91 (Fe _0.8 Ni _0.8 ) ₃ [Fe (CN) ₆ ] ₂ absorption spectrum 92 (Fe _0.6 Ni _0.6 ) ₃ [Fe (CN) ₆ ] ₂ absorption spectrum _{93 (Fe 0.4 Ni 0.4) 3} [Fe (CN) ] ₂ absorption spectrum _{94 (Fe 0.2 Ni 0.2) 3} [Fe (CN) 6] 2 absorption spectrum 101 metal atoms _{M 1}
102 carbon atom 103 nitrogen atom 104 metal atom M ₂

Claims (9)

(A) An aqueous solution containing an anionic metal cyano complex having the metal atom M ₁ as a central metal and an aqueous solution containing a metal cation of the metal atom M ₂ are mixed, and the metal atom M ₁ and the metal atom M ₂ are mixed. A Prussian blue-type metal complex crystal, and (B) a solution in which the ligand L is dissolved in a solvent and the Prussian blue-type metal complex crystal are mixed, (C) A process for producing Prussian blue-type metal complex ultrafine particles, wherein (C) the Prussian blue-type metal complex is separated from the dispersion to form nanometer-sized ultrafine particles. (A) mixing an aqueous solution containing an anionic metal cyanide complex, of which central metal is a metal atom M _1, and an aqueous solution of metal cations the metal atom M _2, having a metal atom M ₁ and metal atom M ₂ Prussian blue-type metal complex crystals are precipitated, and then (B1) an organic solvent solution of ligand L and the Prussian blue-type metal complex crystals are mixed to obtain a dispersion of Prussian blue-type metal complex ultrafine particles. (C) Prussian blue metal complex ultrafine particles in the form of a solid powder having an average particle diameter of 50 nm or less are obtained as an aggregate by removing the solvent from the dispersion. Method for producing blue-type metal complex ultrafine particles.   3. The method for producing Prussian blue-type metal complex ultrafine particles according to claim 2, wherein water is contained in an organic solvent solution in which the ligand L is dissolved. (A) An aqueous solution containing an anionic metal cyano complex having the metal atom M ₁ as a central metal and an aqueous solution containing a metal cation of the metal atom M ₂ are mixed, and the metal atom M ₁ and the metal atom M ₂ are mixed. Next, the Prussian blue-type metal complex crystal having the following structure is precipitated, and then (B2) the Prussian blue-type metal complex crystal and a solution in which the water-soluble ligand L is dissolved in a solvent made of alcohol or water are mixed. (C) By removing the solvent from the dispersion, the aggregate of the solid powdery Prussian blue-type metal complex ultrafine particles having an average particle diameter of 50 nm or less is obtained. The process for producing the Prussian blue-type metal complex ultrafine particles according to claim 1. The metal atom M ₁ is at least one selected from vanadium, chromium, molybdenum, tungsten, manganese, iron, ruthenium, cobalt, nickel, platinum, and copper, and the metal atom M ₂ is vanadium, chromium, manganese, iron, It is at least one selected from ruthenium, cobalt, rhodium, nickel, palladium, platinum, copper, silver, zinc, lanthanum, europium, gadolinium, lutetium, barium, strontium, and calcium, and the ligand L is represented by the following general formula ( The production of Prussian blue-type metal complex ultrafine particles according to any one of claims 1 to 4, which is one or more of the compounds represented by any one of 1) to (3) Method.
(In the formula, R ₁ and R ₂ each independently represent a hydrogen atom or an alkyl group having 8 or more carbon atoms. However, an unsaturated bond may be introduced into these groups.)
(In the formula, R ₃ represents an alkyl group having 8 or more carbon atoms. However, an unsaturated bond may be introduced into this group.)
(In the formula, R ₄ represents an alkyl group having 6 or more carbon atoms, and R ₅ represents an alkyl group. However, an unsaturated bond may be introduced into these groups.) The metal atom M ₁ or M ₂ is two or more kinds of metal atoms, and the mixing amount of the two or more kinds of metal ions is adjusted to obtain Prussian blue-type metal complex ultrafine particles having a target metal composition. The method for producing Prussian blue-type metal complex ultrafine particles according to any one of claims 1 to 5.   7. An optical property adjusting agent is added in preparing (A) Prussian blue-type metal complex crystals and (B) preparing a dispersion of the ultrafine particles. The method for producing the Prussian blue-type metal complex ultrafine particles described in the above item. (A) An aqueous solution containing an anionic metal cyano complex having the metal atom M ₁ as a central metal and an aqueous solution containing a metal cation of the metal atom M ₂ are mixed, and the metal atom M ₁ and the metal atom M ₂ are mixed. A Prussian blue-type metal complex crystal having the following structure: (B) A solution in which the ligand L is dissolved in a solvent and the Prussian blue-type metal complex crystal are mixed to obtain a nanometer-size Prussian A method for producing a dispersion of Prussian blue-type metal complex ultrafine particles, characterized by using a dispersion of blue-type metal complex ultrafine particles. Metal atom M ₁ of Prussian blue-type metal complex crystals and a metal atom M ₁ and metal atom M ₂ is chosen vanadium, chromium, molybdenum, tungsten, manganese, iron, ruthenium, cobalt, nickel, platinum, and copper At least one and the metal atom M ₂ is vanadium, chromium, manganese, iron, ruthenium, cobalt, rhodium, nickel, palladium, platinum, copper, silver, zinc, lanthanum, europium, gadolinium, lutetium, barium, strontium, and It is at least one selected from calcium, and has an average particle diameter of 50 nm or less obtained by coordinating one or more of the compounds represented by any one of the following general formulas (1) to (3) to the crystal Prussian blue type metal complex ultrafine particles characterized by being fine particles.
(In the formula, R ₁ and R ₂ each independently represents a hydrogen atom or an alkenyl group having 8 or more carbon atoms.)
(In the formula, R ₃ represents an alkenyl group having 8 or more carbon atoms.)
(In the formula, R ₄ represents an alkenyl group having 6 or more carbon atoms, and R ₅ represents an alkyl group or an alkenyl group.)