JP2019041028A - Nanomaterial composite and method for producing the same - Google Patents

Abstract

To provide an inexpensive nanomaterial composite having excellent thermoelectric properties and thermal stability.SOLUTION: A polyethylene glycol derivative containing polyethylene glycol derivatives, metal cations, and n-type nanomaterials has a chain structure represented by the following formula (1). In the formula (1), n is an integer of 4 or more. -(CHCHO)- ...(1)SELECTED DRAWING: Figure 1

Description

  The present invention relates to a nanomaterial composite and a method for producing the same.

  In recent years, in order to construct flexible elements or miniaturized elements in fields such as thermoelectric conversion elements, field effect transistors, sensors, integrated circuits, rectifying elements, solar cells, catalysts, and electroluminescence The use of nanomaterials is attracting attention.

  In general, in the above field, it is preferable to use a bipolar element provided with both a material exhibiting p-type conductivity (p-type material) and a material exhibiting n-type conductivity (n-type material). For example, a thermoelectric conversion element is an element used for thermoelectric power generation. In thermoelectric power generation, electric power is generated by utilizing a potential difference generated in a substance due to a temperature difference. Specifically, FIG. 1 shows a schematic diagram illustrating an example of a bipolar thermoelectric conversion device including an n-type material and a p-type material. If it is a bipolar thermoelectric conversion device, it can generate electric power efficiently by connecting n type material and p type material in series.

  By the way, Patent Document 1 discloses a thermoelectric conversion material containing a conductive polymer and a thermal excitation assist agent. Patent Document 2 discloses a thermoelectric conversion material containing a carbon nanotube and a conjugated polymer.

  Further, Non-Patent Document 1 describes a conductive film using poly (3,4-ethylenedioxythiophene) (PEDOT). Non-Patent Document 2 describes a composite material using a composite of PEDOT and poly (styrene sulfonic acid) (PEDOT: PSS) or meso-tetra (4-carboxyphenyl) porphine (TCPP) and carbon nanotubes. ing. The carbon nanotubes utilized in the techniques described in Patent Document 2 and Non-Patent Document 2 are mainly p-type materials. Thus, nanomaterials often exhibit p-type conductivity. Therefore, a technique for converting a p-type material into an n-type material is required.

  However, regarding the n-type material, as described in Non-Patent Document 3, the n-type organic material, the n-type carbon material, or the additive inherently has an unstable chemical bond, and thus has stabilized. It was common technical knowledge in the field that it was difficult to obtain an n-type material. Under such circumstances, the present inventors have developed a technique described in Patent Document 3, for example, as a technique for converting a p-type material into an n-type material.

International Publication No. 2013/047730 (Released on April 4, 2013) International Publication No. 2013/065631 (Released on May 10, 2013) International Publication No. 2015/198980 (Released on December 30, 2015)

T. Park et. Al., Energy Environ. Sci. 6, 788-792, 2013 G. P. Moriarty et al., Energy Technol. 1, 265-272, 2013 D. M. de Leeuw et al., Synth. Met. 87, 53-59, 1997

  However, from the viewpoint of realizing an n-type material exhibiting an output comparable to the p-type material, there is room for further improvement in the above-described conventional technology. Moreover, since it is necessary to use an expensive material (specifically, crown ether), the invention described in Patent Document 3 has a problem of reducing raw material costs for mass production of n-type materials.

  One embodiment of the present invention has been made in view of the above problems, and an object thereof is to provide an inexpensive nanomaterial composite having excellent thermoelectric properties and thermal stability.

  As a result of intensive studies to solve the above-mentioned problems, the present inventors have achieved excellent thermoelectric properties and heat by using a polyethylene glycol derivative having a specific structure, a metal cation, and an n-type nanomaterial. It has been found that an inexpensive nanomaterial composite having stability can be provided, and the present invention has been completed.

That is, the present invention includes the inventions described in [1] to [11] below.
[1] A polyethylene glycol derivative, a metal cation, and an n-type nanomaterial,
The polyethylene glycol derivative has a chain structure represented by the following formula (1):
_{- (CH 2 CH 2 O)} n - ··· (1)
In formula (1), n is an integer of 4 or more.
[2] The nanomaterial composite according to [1], wherein the polyethylene glycol derivative has a hydrophobic group.
[3] The nanomaterial composite according to [1] or [2], wherein the polyethylene glycol derivative is a nonionic surfactant.
[4] The nonionic surfactant is at least selected from the group consisting of a polyoxyethylene / polyoxypropylene block polymer, a polyoxyethylene sorbitan fatty acid ester, a polyoxyethylene alkylphenyl ether, and a polyoxyethylene alkyl ether. The nanomaterial composite according to [3], wherein the composite is one.
[5] Any one of [1] to [4], wherein the n-type nanomaterial includes at least one selected from the group consisting of nanoparticles, nanotubes, nanowires, nanorods, and nanosheets. A nanomaterial composite according to 1.
[6] An ink comprising the nanomaterial composite according to any one of [1] to [5] and a solvent.
[7] A step of bringing a polyethylene glycol derivative and a metal cation into contact with an n-type nanomaterial, wherein the polyethylene glycol derivative has a chain structure represented by the following formula (1) Manufacturing method of material composite:
_{- (CH 2 CH 2 O)} n - ··· (1)
In formula (1), n is an integer of 4 or more.
[8] The method for producing a nanomaterial composite according to [7], wherein the polyethylene glycol derivative has a hydrophobic group.
[9] The method for producing a nanomaterial composite according to [7] or [8], wherein the polyethylene glycol derivative is a nonionic surfactant.
[10] The nonionic surfactant is at least selected from the group consisting of a polyoxyethylene / polyoxypropylene block polymer, a polyoxyethylene sorbitan fatty acid ester, a polyoxyethylene alkylphenyl ether, and a polyoxyethylene alkyl ether. It is one, The manufacturing method of the nanomaterial composite_body | complex as described in [9] characterized by the above-mentioned.
[11] Any one of [7] to [10], wherein the n-type nanomaterial includes at least one selected from the group consisting of nanoparticles, nanotubes, nanowires, nanorods, and nanosheets. The manufacturing method of the nanomaterial composite_body | complex described in 2.

  According to one embodiment of the present invention, an inexpensive nanomaterial having excellent thermoelectric properties and thermal stability by using a polyethylene glycol derivative having a specific structure, a metal cation, and an n-type nanomaterial. There exists an effect that a composite_body | complex can be provided.

It is the schematic diagram which showed an example of the bipolar thermoelectric conversion element provided with n-type material and p-type material. It is a figure which shows the measurement result of the absorption spectrum in the Example of this application. (A) is a figure which shows the measurement result of the Seebeck coefficient in Example 1, and electrical conductivity. (B) is a figure which shows the calculation result of the output factor in Example 1. FIG. It is a figure which shows the measurement result of the electrical conductivity and Seebeck coefficient in the Example of this application, and the calculation result of an output factor.

  Hereinafter, although an example of an embodiment of the invention is explained in detail, the present invention is not limited to these. Unless otherwise specified in this specification, “A to B” indicating a numerical range means “A or more and B or less”.

[1. Indices on thermoelectric properties of nanomaterial composites]
First, an index related to thermoelectric properties of the nanomaterial composite will be described. An example of the index is an output factor (power factor). The output factor is obtained by the following equation (i).

PF = α ² σ (i)
In formula (i), PF is an output factor, α is a Seebeck coefficient, and σ is conductivity. In nanomaterials complexes, for example, it is preferable that the output factor is 100 .mu.W / mK ² or more at 310K, more preferably 200μW / mK ² or more, further preferably 400 W / mK ² or more. It is preferable that the output factor of the nanomaterial composite is 100 μW / mK ² or more at 310K because it is equal to or exceeds that of the conventional p-type nanomaterial composite. In order to obtain such a high-power n-type nanomaterial composite, it is conceivable to improve either the Seebeck coefficient or the conductivity, or both.

  The Seebeck coefficient is the ratio of the open circuit voltage to the temperature difference between the high-temperature junction and the low-temperature junction of the circuit showing the Seebeck effect (from “Maglow Hill Science and Technology Terms Dictionary 3rd edition”). The Seebeck coefficient can be measured using, for example, a Seebeck effect measuring device (manufactured by MMR Technologies) or a thermoelectric conversion property evaluating device (ZEM-3, manufactured by Advance Riko Co., Ltd.) used in Examples described later. The larger the absolute value of the Seebeck coefficient, the greater the thermoelectromotive force.

  Further, the sign of the Seebeck coefficient can be an indicator of whether the carbon nanotube or the like has p-type conductivity or n-type conductivity. Specifically, when the Seebeck coefficient shows a positive value, it can be said that it has p-type conductivity. On the other hand, when the Seebeck coefficient shows a negative value, it can be said that it has n-type conductivity.

  In the nanomaterial composite, the Seebeck coefficient is preferably −20 μV / K or less, more preferably −30 μV / K or less, and further preferably −40 μV / K or less. However, when power generation is performed using minute energy such as a low-temperature heat source, there is a case where it is necessary to suppress impedance required for the booster circuit due to increase in conductivity as well as increase in thermoelectromotive force. In this case, the Seebeck coefficient of the nanomaterial composite is more preferably −250 to −20 μV / K.

  The conductivity is, for example, a four-probe method using a resistivity meter (Mitsubishi Chemical Analytech Co., Ltd., Loresta GP) or a thermoelectric conversion characteristic evaluation device (Advanced Chemistry Co., Ltd., ZEM-3) used in Examples described later. Can be measured.

  In the nanomaterial composite, the electrical conductivity is preferably 1000 S / cm or more, more preferably 1500 S / cm or more, and further preferably 2000 S / cm or more. A conductivity of 1000 S / cm or more is preferable because the nanomaterial composite has high output.

[2. Nanomaterial composite)
A nanomaterial composite according to an embodiment of the present invention (hereinafter also referred to as the present nanomaterial composite) includes a polyethylene glycol derivative, a metal cation, and an n-type nanomaterial, and the polyethylene glycol derivative has the following formula: It has a chain structure represented by (1).
_{- (CH 2 CH 2 O)} n - ··· (1)
In formula (1), n is an integer of 4 or more.

The polyethylene glycol derivative has a chain structure represented by the formula (1) (hereinafter also referred to as “PEG chain”). The PEG chain portion in the polyethylene glycol derivative is coordinated to the metal cation to form a complex. At this time, the complex of the polyethylene glycol derivative and the metal cation is considered to form a structure similar to the complex of polyethylene glycol (for example, crown ether) having a cyclic structure and the metal cation. For example, as shown in (I) below, when a metal salt (NaX) and a polyethylene glycol derivative in which n is 6 are dispersed in a solution, a metal cation (Na ⁺ (sodium ion)) and n in which PEG is 6 The chain is considered to form a complex in which the metal cation and the non-covalent bond on the oxygen of the PEG chain are coordinated and the PEG chain surrounds the metal cation. The structure of this complex is considered to be similar to the structure of a complex formed by coordination of a crown ether (for example, 15-crown-5) and a sodium ion.

  The polyethylene glycol derivative can solvate metal cations through unshared electron pairs on oxygen of the PEG chain. At this time, the anion which is a counter ion is unstable and highly reactive because it is shielded from positive charges by a bulky polyethylene glycol derivative. Utilizing this fact, it is considered that a reduction reaction by an anion, that is, electron injection into the nanomaterial, is performed, and the nanomaterial becomes n-type. Note that, as will be described later, the method for converting the nanomaterial to n-type is not limited to electron injection into the nanomaterial.

  The n-type nanomaterial is in a state in which negative charges are delocalized and is a soft base. On the other hand, the complex is a soft acid with a positive charge delocalized. A soft base can be stabilized by the action of a soft acid. Therefore, the present nanomaterial composite exhibits stable n-type conductivity by allowing a complex of a polyethylene glycol derivative and a metal cation to act on the n-type nanomaterial. The definition of soft acids and bases is based on HSAB theory (R. G. Pearson, J. Am. Chem. Soc. 85 (22), 3533-3539, 1963).

  The nanomaterial composite may contain a substance other than the polyethylene glycol derivative, the metal cation, and the n-type nanomaterial as necessary. Such a substance is not particularly limited as long as it does not inhibit the above-described effect due to the complex.

<2-1. Polyethylene glycol derivative>
The nanomaterial composite includes a polyethylene glycol derivative. The polyethylene glycol derivative has a chain structure represented by the following formula (1),
_{- (CH 2 CH 2 O)} n - ··· (1)
In formula (1), n is an integer of 4 or more.

  In the present specification, the expression “polyethylene glycol derivative” refers to a compound having at least a PEG chain represented by the formula (1) and further having various end groups regardless of a hydrophobic group or a hydrophilic group. Intended. The terminal of formula (1) may be a hydrogen atom or a hydroxyl group. The polyethylene glycol derivative may have one PEG chain or a plurality of PEG chains. In addition, the polyethylene glycol derivative may be chained or branched. However, the polyethylene glycol derivative is not cyclic (that is, excluding crown ether).

  In the formula (1), when n is an integer of 4 or more, as described above, the polyethylene glycol derivative and the metal cation form a complex so that the PEG chain surrounds the metal cation and shields the positive charge. it can.

  The polyethylene glycol derivative is not particularly limited as long as it has a chain structure represented by the formula (1) where n is 4 or more. For example, polyoxyethylene alkyl ether sulfate, polyoxyethylene benzyl phenyl ether sulfate, polyoxyethylene phenyl ether sulfate, polyoxyethylene alkyl ether phosphate, polyoxyethylene benzyl phenyl ether phosphate, polyoxyethylene phenyl Ether phosphate, polyoxyethylene alkyl ether sulfonate, polyoxyethylene benzyl phenyl ether sulfonate, polyoxyethylene phenyl ether sulfonate, polyoxyethylene fatty acid ester, polyoxyethylene resin acid ester, polyoxyethylene fatty acid Diester, polyoxyethylene dialkyl phenyl ether, polyoxyethylene alkylamine, polyoxyethylene fatty acid amide, polyoxyethylene Fatty acid bisphenyl ether, polyoxyethylene benzyl phenyl ether, polyoxyethylene castor oil, polyoxyethylene hydrogenated castor oil, polyoxyethylene / polyoxypropylene block polymer, polyoxyethylene sorbitan fatty acid ester, polyoxyethylene alkylphenyl ether, and Examples include polyoxyethylene alkyl ether.

  The polyethylene glycol derivative preferably has a hydrophobic group. The polyethylene glycol derivative having a hydrophobic group is preferable because it exhibits amphipathic properties and is easily dispersed in a solvent such as water and an organic solvent. Examples of hydrophobic groups include saturated or unsaturated cyclic hydrocarbon groups, acyclic hydrocarbon groups (which may be chained or branched), aromatic groups, halogen groups, and the like. Can be mentioned. The polyethylene glycol derivative preferably has a hydrophobic group as a part of the terminal group of the formula (1). For example, the hydrophobic group is an alkyl group, an alkylene group, a phenylene group, or a polypropylene oxide chain (PPO chain). It may be.

  The polyethylene glycol derivative is preferably a nonionic surfactant. If the polyethylene glycol derivative is a nonionic surfactant, it is preferable because it is easily dispersed in a solvent such as water. In addition, it is preferable that the polyethylene glycol derivative is a nonionic surfactant because it is not ionized in a solvent and thus has little influence on the electronic state of the n-type nanomaterial. Examples of the nonionic surfactant include polyoxyethylene fatty acid ester, polyoxyethylene resin acid ester, polyoxyethylene fatty acid diester, polyoxyethylene dialkyl phenyl ether, polyoxyethylene alkylamine, polyoxyethylene fatty acid amide, Polyoxyethylene fatty acid bisphenyl ether, polyoxyethylene benzyl phenyl ether, polyoxyethylene castor oil, polyoxyethylene hydrogenated castor oil, polyoxyethylene / polyoxypropylene block polymer, polyoxyethylene sorbitan fatty acid ester, polyoxyethylene alkylphenyl Examples include ethers and polyoxyethylene alkyl ethers.

  As the nonionic surfactant, polyoxyethylene / polyoxypropylene block polymer, polyoxyethylene sorbitan fatty acid ester, polyoxyethylene alkylphenyl ether, and polyoxyethylene are used because they are inexpensive and can be obtained. Alkyl ethers are preferred.

  Examples of the polyoxyethylene / polyoxypropylene block polymer include polyoxyethylene (196) polyoxypropylene (67) glycol (for example, product name: Pluronic (registered trademark) F127), polyoxyethylene (160) polyoxypropylene. (30) glycol (for example, product name: Pluronic (registered trademark) F-68), polyoxyethylene (300) polyoxypropylene (55) glycol (for example, product name: Pluronic (registered trademark) F-108), etc. Pluronic (registered trademark) surfactants may be mentioned.

  Examples of polyoxyethylene sorbitan fatty acid esters include polyoxyethylene sorbitan mono-laurate (eg, product name: Tween® 20), polyoxyethylene sorbitan mono-palmitate (eg, product name: Tween®) 40), polyoxyethylene sorbitan mono-stearate (for example, product name: Tween® 60), polyoxyethylene sorbitan mono-oleate (for example, product name: Tween® 80), polyoxyethylene sorbitan Examples include Tween (registered trademark) -based surfactants such as trioleate (for example, product name: Tween (registered trademark) 85).

  Examples of polyoxyethylene alkylphenyl ether include polyoxyethylene (10) octylphenyl ether (for example, product name: Triton (registered trademark) X-100), polyoxyethylene (40) isooctylphenyl ether (for example, product) Name: Triton (registered trademark) X-405) and other Triton (registered trademark) surfactants; poly (oxyethylene) p-octylphenyl ether (for example, product name: Nonidet (registered trademark) P-40); octyl And phenyl polyethylene glycol (for example, product name: Igepal (registered trademark) CA-630).

  Examples of the polyoxyethylene alkyl ether include polyoxyethylene (23) lauryl ether (for example, product name: Brij (registered trademark) 35), polyoxyethylene (20) cetyl ether (for example, product name: Brij (registered trademark)). 58), polyoxyethylene (20) stearyl ether (for example, product name: Brij (registered trademark) 78), polyoxyethylene (10) oleyl ether (for example, product name: Brij (registered trademark) 97), polyoxy Ethylene (10) cetyl ether (for example, product name: Brij (registered trademark) 56), polyoxyethylene (10) stearyl ether (for example, product name: Brij (registered trademark) 76), polyoxyethylene (20) oleyl ether (For example, product name: Brij (registered trademark) 98), Oxyethylene (100) stearyl ether (e.g., product name: Brij (R) S100) such Brij (registered trademark) surfactants.

  As the nonionic surfactant, Pluronic (registered trademark) F127, Pluronic (registered trademark) F-68, Pluronic (registered trademark) F-108, and TWEEN (registered trademark) 80 are used because they are inexpensive and easily available. Commercial products such as Triton (registered trademark) X-100 and Brij (registered trademark) S100 are more preferable.

<2-2. Metal Cations>
The nanomaterial composite includes a metal cation.

  Examples of metal cations include typical metal ions (alkali metal ions and alkaline earth metal ions) and transition metal ions. The metal cation may be, for example, lithium ion, sodium ion, potassium ion, rubidium ion, cesium ion, francium ion, beryllium ion, magnesium ion, calcium ion, strontium ion, barium ion, radium ion and scandium ion. Good.

  Among the metal cations described above, sodium ion, potassium ion, rubidium ion and cesium ion are preferable from the viewpoint of easy availability.

<2-3. n-type nanomaterials>
The nanomaterial composite includes an n-type nanomaterial, that is, an n-type nanomaterial. In this specification, the “nanomaterial” means a substance having a dimension in a nanoscale (for example, 100 nm or less) in at least one direction. The nanomaterial is, for example, a carbon nanotube.

  The method for making the nanomaterial n-type is not particularly limited, and examples thereof include a method in which an n-type dopant (for example, a specific anion) is allowed to act on the nanomaterial. More specifically, the process (ii) mentioned later is mentioned.

  The nanomaterial may be a low-dimensional nanomaterial. In this specification, “low dimension” intends a dimension smaller than three dimensions. That is, in this specification, “low dimension” means zero dimension, one dimension, or two dimensions. In the present specification, “low-dimensional nanomaterial” intends a nanomaterial that can substantially define a three-dimensional structure in “low dimension”.

  Examples of zero-dimensional nanomaterials include nanoparticles (quantum dots). Examples of the one-dimensional nanomaterial include nanotubes, nanowires, and nanorods. An example of the two-dimensional nanomaterial is a nanosheet. Preferably, the nanomaterial includes at least one selected from the group consisting of nanoparticles, nanotubes, nanowires, nanorods, and nanosheets.

  The n-type nanomaterial may include at least one selected from the group consisting of carbon, semiconductor, metalloid, and metal. The n-type nanomaterial may be a nanomaterial made of at least one selected from the group consisting of carbon, semiconductor, metalloid and metal. From the viewpoint of light weight and flexibility derived from a carbon-carbon bond, the nanomaterial is preferably a nanomaterial made of carbon. Examples of the nanomaterial made of carbon include carbon nanotubes and graphene (that is, nanosheets made of carbon). In the present specification, the carbon nanotube may be referred to as “CNT”.

  Examples of the semiconductor include iron silicide, sodium cobaltate, and antimony telluride. Examples of the semimetal include tellurium, boron, germanium, arsenic, antimony, selenium, and graphite. Examples of the metal include gold, silver, copper, platinum, and nickel.

  The nanotube and the nanosheet may have a single-layer structure or a multilayer structure (two-layer, three-layer, four-layer, or more layers). For example, the n-type nanomaterial may be a single-walled carbon nanotube or a multi-walled carbon nanotube.

  The nanomaterial composite can be used in various applications and applications as a thermoelectric conversion device. Here, it is preferable that the thermoelectric conversion device has flexibility because it can be brought into close contact with a complicated three-dimensional surface such as a human body and piping, and body temperature and waste heat can be used efficiently. From the viewpoint of imparting excellent mechanical properties (such as tensile strength, Young's modulus and elastic modulus) to the nanomaterial composite in order to increase the flexibility of the thermoelectric conversion device, the n-type nanomaterial is a single-layer carbon. Nanotubes are preferred.

In the nanomaterial composite, the n-type nanomaterial may be formed into a desired shape. For example, the nanomaterial composite may include a film in which nanomaterials are integrated. Here, the “film” is also referred to as a sheet or a membrane. For example, the film may have a thickness of 0.1 μm to 1000 μm. The density of the film is not particularly limited, it may be 0.05 to 1.0 g / cm ^3, may be 0.1 to 0.5 g / cm ^3. The film has a non-woven structure so that the nanomaterials are intertwined with each other. Therefore, the film is lightweight and has flexibility.

<2-4. Ink>
An ink according to an embodiment of the present invention (hereinafter also referred to as the present ink) includes a nanomaterial composite and a solvent.

  The nanomaterial composite may be formed into a desired shape (for example, a film) or may not be formed. When the nanomaterial composite is molded, for example, the ink can be produced by dispersing the molded nanomaterial composite in a solvent. When the nanomaterial composite is not molded, for example, the ink can be produced by dispersing the nanomaterial composite in a solvent. In addition, [3. As described later in the method for producing a nanomaterial composite], step (i) (that is, a step of bringing a polyethylene glycol derivative and a metal cation into contact with an n-type nanomaterial) or step (i) and step (ii) The nanomaterial composite itself produced by performing both (that is, the step of converting the nanomaterial into n-type) may be used as the ink.

  The concentration of the nanomaterial complex in the ink is preferably 0.1 to 1000 mM, and more preferably 10 to 100 mM. The concentration of the nanomaterial composite in the ink can be calculated from the mass of the carbon nanotube in the ink, for example, when the nanomaterial is a carbon nanotube, with the atomic weight of carbon being 12.

  The solvent may be appropriately selected from those suitable for use as an ink, and examples thereof include water and organic solvents. Examples of organic solvents include toluene, o-dichlorobenzene, tetrahydrofuran and chloroform. The solvent is preferably water from the viewpoint that it is easy to handle, is relatively safe, has good dispersibility of the nanomaterial composite, and can be used for various applications.

  The ink may contain a substance other than the nanomaterial composite and the solvent, if necessary. Such a substance is not particularly limited as long as it does not impair the thermoelectric properties of the nanomaterial composite.

  The ink is used by being applied on a substrate, for example.

  As the substrate, a substrate such as glass, transparent ceramics, metal, or plastic film can be used.

  Although the thickness of the said board | substrate is not specifically limited, 1 micrometer-1000 micrometers are preferable.

  The method for applying the ink on the substrate is not particularly limited, but spin coating, extrusion die coating, blade coating, bar coating, screen printing, stencil printing, roll coating, curtain coating, spray coating, dip coating, inkjet printing, A known coating method such as dispensing can be used.

  Further, various devices suitable for ink application can be used and are not particularly limited.

  With this ink, it becomes possible to design thermoelectric conversion devices of various shapes that can efficiently generate power. In addition, a thermoelectric conversion device that is flexible and reduced in size and weight can be realized.

[3. Method for producing nanomaterial composite]
A method for producing a nanomaterial composite according to an embodiment of the present invention (hereinafter also referred to as the present production method) includes a step of bringing a polyethylene glycol derivative and a metal cation into contact with an n-type nanomaterial, The derivative is characterized by having a chain structure represented by the following formula (1).
_{- (CH 2 CH 2 O)} n - ··· (1)
In formula (1), n is an integer of 4 or more.

  In addition, [2. Regarding the matters already described in [Nanomaterial Composite], the description is omitted below, and the above description is used as appropriate.

  Hereinafter, the step of bringing the polyethylene glycol derivative and the metal cation into contact with the n-type nanomaterial is referred to as step (i).

  In the step (i), the n-type nanomaterial may be brought into contact with the polyethylene glycol derivative and the metal cation, and the method is not particularly limited. From the viewpoint of sufficiently bringing the n-type nanomaterial, the polyethylene glycol derivative, and the metal cation into contact, a method of bringing the solution containing the polyethylene glycol derivative and the metal cation into contact with the nanomaterial is preferable. Specifically, a method of impregnating the nanomaterial with the solution or a method of bringing the nanomaterial into contact with the solution by shearing and dispersing the nanomaterial in the solution is preferable.

  The solvent in the solution may be water or an organic solvent. The solvent is preferably an organic solvent, more preferably methanol, ethanol, propanol, butanol, acetonitrile, N, N-dimethylformamide, dimethyl sulfoxide or N-methylpyrrolidone. Examples of propanol include 1-propanol and 2-propanol. Examples of butanol include 1-butanol and 2-butanol.

  The concentration of the polyethylene glycol derivative and the metal cation ion in the solution may be any concentration, preferably 1 to 1000 mM, and more preferably 10 to 100 mM.

  Examples of the method of impregnating the solution with the nanomaterial include a method of immersing a nanomaterial (for example, a film) formed into a desired shape as described later in the solution. Examples of the method of shearing and dispersing the nanomaterial in the solution include a method of dispersing the nanomaterial in the solution using a homogenizer.

  The homogenizer is not particularly limited as long as it can uniformly disperse the nanomaterial in the solution. For example, known means such as a stirring homogenizer or an ultrasonic homogenizer can be used.

  The operating condition of the homogenizer is not particularly limited as long as the nanomaterial can be dispersed in the solution. For example, when a stirring homogenizer is used as a homogenizer, the nanomaterial is treated by treating the solution to which the nanomaterial has been added at a stirring speed (number of rotations) of 20000 rpm for 10 minutes at room temperature (23 ° C.). Can be dispersed in.

  Moreover, in the case of the method of immersing the shaped nanomaterial in the solution, the time for immersing is not particularly limited, but is preferably 10 to 600 minutes, more preferably 100 to 600 minutes, and 200 to 600 minutes. More preferably.

  In addition, before the step (i), a step (ii) a step of converting the nanomaterial into an n-type may be included. The method for converting the nanomaterial into n-type is not particularly limited, and examples thereof include a method of causing a specific anion to act on the nanomaterial.

  Step (ii) may be performed simultaneously with step (i). In this case, for example, the nanomaterial is brought into contact with a solution in which a metal salt that generates an anion and a metal cation when dissolved in a solvent and a polyethylene glycol derivative are dissolved. From the viewpoint of efficiently forming a complex, the solution preferably contains a metal cation and a polyethylene glycol derivative so that the molar ratio thereof is 1: 1.

  The anion changes the carrier of the nanomaterial from a hole to an electron. As a result, the Seebeck coefficient of the nanomaterial changes and the nanomaterial is negatively charged.

Examples of anions include hydroxy ions (OH ⁻ ), alkoxy ions (CH ₃ O ⁻ , CH ₃ CH ₂ O ⁻ , i-PrO ⁻ and t-BuO ⁻ etc.), thio ions (SH ⁻ and CH ₃ S ^−). And alkylthio ions such as C ₂ H ₅ S ⁻ ), cyanuric ions (CN ⁻ ), I ⁻ , Br ⁻ , Cl ⁻ , BH ₄ ⁻ , carboxy ions (CH ₃ COO ^{− and the} like), CO ₃ ²⁻ , HCO ₃ ⁻ , NO ₃ ⁻ , BF ₄ ⁻ , ClO ₄ ⁻ , TfO ⁻ , Tos ^{− and the} like can be mentioned. Among these, anions include OH ⁻ , CH ₃ O ⁻ , CH ₃ CH ₃ O ⁻ , i-PrO ⁻ , t-BuO ⁻ , SH ⁻ , CH ₃ S ⁻ , C ₂ H ₅ S ⁻ , CN ⁻ , I ^{-, Br -, Cl -,} BH 4 -, and _CH 3 COO ^- is preferably at least one selected from the group consisting of, OH ^- and _CH 3 O ^- and more preferably at least one of . According to the anion, the Seebeck coefficient of the nanomaterial can be changed efficiently.

  One reason that the anion acts as a dopant for converting the nanomaterial to n-type is that the anion has an unshared electron pair. The anion is presumed to interact with the nanomaterial to be doped or to induce a chemical reaction based on its unshared electron pair. In addition, the Lewis basicity, intermolecular force, and dissociation properties of the dopant are considered to be important in doping efficiency.

  In the present specification, “Lewis basic” means the property of donating an electron pair. It is considered that a dopant having strong Lewis basicity has a greater influence on the change in Seebeck coefficient.

Moreover, it is thought that the intermolecular force of the dopant is also related to the adsorptivity of the dopant to the nanomaterial. Examples of the intermolecular force of the dopant include a hydrogen bond, CH-π interaction, and π-π interaction. Among the anions, anions that give weak hydrogen bonds are preferable. Examples of the anion that gives a weak hydrogen bond include OH ⁻ , CH ₃ O ⁻ , CH ₃ CH ₂ O ⁻ , i-PrO ^−, and t-BuO ⁻ . Further, the anion is preferably an anion that imparts a π-π interaction. As an example of the anion which gives a π-π interaction, for example, CH ₃ COO ^— can be mentioned.

  This production method may include a step (iii) of forming the film by integrating the nanomaterial before or after the step (i). That is, the step (iii) may be a step of forming the nanomaterial into a desired shape (for example, a film) before the step (i), and the nanomaterial obtained by the step (i) may be a desired shape. It may be a step of forming into a shape.

  An example of a method for forming a film is not particularly limited, and examples thereof include a method of forming a film by dispersing a nanomaterial in a solvent and filtering the obtained dispersion on a membrane filter. Specifically, the nanomaterial dispersion is subjected to suction filtration using a membrane filter having a pore size of 0.1 to 2 μm, and the membrane remaining on the membrane filter is subjected to 50 to 150 ° C. for 1 to 24 hours. The film can be formed by drying under reduced pressure. Alternatively, the nanomaterial dispersion may be centrifuged, and the supernatant may be filtered on a membrane filter to form a film.

  The solvent in which the nanomaterial is dispersed may be water or an organic solvent. The solvent is preferably an organic solvent, and more preferably o-dichlorobenzene, bromobenzene, 1-chloronaphthalene, 2-chloronaphthalene or cyclohexanone. With these solvents, the nanomaterial can be efficiently dispersed.

  As a method of dispersing the nanomaterial, a method similar to the method of dispersing the nanomaterial in the solution using the homogenizer in the above step (i) can be used.

  The present invention is not limited to the above-described embodiments, and various modifications are possible within the scope shown in the claims, and embodiments obtained by appropriately combining technical means disclosed in different embodiments. Is also included in the technical scope of the present invention.

  EXAMPLES Hereinafter, although this invention is demonstrated in detail based on an Example, a comparative example, and a reference example, this invention is not limited to a following example.

[Identification of electronic states]
In order to confirm whether the nanomaterial can be made n-type by using a polyethylene glycol derivative, the absorbance of the measurement sample is measured using a Fourier transform infrared spectrophotometer (product name: HYPERION 2000, manufactured by Bruker Optics). Thus, the electronic state of the nanomaterial was identified.

5 mg of CNT (manufactured by Meijo Nanocarbon Co., Ltd., product name: EC-2.0), potassium carbonate (K ₂ CO ₃ , manufactured by Wako Pure Chemical Industries, Ltd.) at a specified concentration (1 mM, 10 mM, 100 mM) and 1% by weight In an aqueous solution of Pluronic (registered trademark) F127 (manufactured by BASF) by ultrasonic irradiation for 10 minutes. For dispersion, an ultrasonic homogenizer (manufactured by Qsonica, Q125) was used. Subsequently, the obtained dispersion is centrifuged at 10,000 rpm for 30 minutes using a centrifuge (Kubota Corporation, product name: table top cooling centrifuge 5500). Qing was recovered. The supernatant was filtered and dried using a membrane filter (0.2 μm pore, manufactured by Merck Millipore, product name: Omnipore Membrane Filter JGWP02500), and then the CNT film deposited on the filter was PET film (Teijin Film Solutions Co., Ltd.) Product, product name: Teijin (registered trademark) Tetron (registered trademark) film G2) was used as a measurement sample.

The measurement results are shown in FIG. As shown in FIG. 2, a decrease in the band gap absorption of S ₁₁ was observed as the concentration of potassium carbonate (ie, metal cation and anion) used was increased. This suggests the injection of electrons into the conduction band, that is, the conversion of CNT to n-type. Further, since the absorption spectrum of S ₂₂ disappears as the concentration of potassium carbonate (that is, metal cation and anion) is increased, electrons equivalent to the case of doping using crown ether as described in Patent Document 3 are used. I found out that there was a move.

[Evaluation of thermoelectric properties]
(A) Conductivity For the measurement samples obtained in the examples, comparative examples and reference examples described later, by a four-probe method using a thermoelectric conversion characteristic evaluation apparatus (manufactured by Advance Riko Co., Ltd., product name: ZEM-3). Conductivity was measured. The measurement temperature was 310 K (37 ° C.).

(B) Seebeck coefficient The Seebeck coefficient of the measurement samples obtained in the examples, comparative examples and reference examples described below was measured using a thermoelectric conversion characteristic evaluation apparatus (manufactured by Advance Riko Co., Ltd., product name: ZEM-3). . The measurement temperature was 310 K (37 ° C.).

(C) Output factor For the measurement samples obtained in the examples, comparative examples and reference examples described later, the output factor according to the following formula (i) using the conductivity σ and the Seebeck coefficient α obtained by the above-described method. PF was calculated.

PF = α ² σ (i)
[Comparison of thermoelectric properties]
<Example 1>
5 mg of CNT (manufactured by Meijo Nanocarbon Co., Ltd., product name: EC-2.0) at a specified concentration (0.1 mM, 0.25 mM, 0.5 mM, 1 mM, 2.5 mM, 5 mM, 10 mM, 50 mM, 100 mM) Of potassium carbonate (K ₂ CO ₃ , manufactured by Wako Pure Chemical Industries, Ltd.) and 1 wt% Pluronic (registered trademark) F127 (manufactured by BASF) was dispersed by ultrasonic irradiation for 10 minutes. For dispersion, an ultrasonic homogenizer (manufactured by Qsonica, Q125) was used. Subsequently, the obtained dispersion is centrifuged at 10,000 rpm for 30 minutes using a centrifuge (Kubota Corporation, table top cooling centrifuge 5500), and a supernatant of about 70% by volume is recovered. did. The supernatant was filtered and dried using a membrane filter (0.2 μm pore, manufactured by Merck Millipore, product name: Omnipore Membrane Filter JGWP02500), and then the CNT film deposited on the filter was PET film (Teijin Film Solutions Co., Ltd.) Product, product name: Teijin (registered trademark) Tetron (registered trademark) film G2) was used as a measurement sample. Note that the concentration of the nanomaterial composite in the dispersion was about 20 mM.

  For each measurement sample, the measurement result of the conductivity and Seebeck coefficient is shown in FIG. 3A, and the calculation result of the output factor is shown in FIG. 3B. Table 1 shows specific numerical values of conductivity, Seebeck coefficient, and output factor for each measurement sample.

  As shown in FIGS. 3A and 3 and Table 1, it was found that the thermoelectric characteristics continuously changed as the concentration of potassium carbonate used was changed. That is, in the present invention, thermoelectric characteristics can be controlled by changing the amount of metal salt added.

<Example 2>
In Example 1, except that 100 mM potassium carbonate (K ₂ CO ₃ , manufactured by Wako Pure Chemical Industries, Ltd.) was used and Pluronic (registered trademark) F108 (manufactured by BASF) was used instead of Pluronic (registered trademark) F127. A measurement sample was prepared in the same manner as in Example 1.

<Example 3>
In Example 1, except that 100 mM potassium carbonate (K ₂ CO ₃ , manufactured by Wako Pure Chemical Industries, Ltd.) was used and Brij (registered trademark) S100 (manufactured by Croda) was used instead of Pluronic (registered trademark) F127. A measurement sample was prepared in the same manner as in Example 1.

<Example 4>
Disperse 5 mg of CNTs in an aqueous solution of 100 mM potassium carbonate (K ₂ CO ₃ , manufactured by Wako Pure Chemical Industries) and 1% by weight Pluronic (registered trademark) F127 (manufactured by BASF) by ultrasonic irradiation for 10 minutes. I let you. For dispersion, an ultrasonic homogenizer (manufactured by Qsonica, Q125) was used. The obtained dispersion was filtered and dried using a membrane filter (0.2 μm pore, Merck Millipore, Omnipore membrane filter JGWP02500), and then the CNT film deposited on the filter was PET film (manufactured by Teijin Film Solutions). Product name: Teijin (registered trademark) Tetron (registered trademark) film G2) was used as a measurement sample.

<Comparative Example 1>
In Example 1, the concentration of potassium carbonate (K ₂ CO ₃ , manufactured by Wako Pure Chemical Industries, Ltd.) was set to 100 mM, and 18-crown-6-ether (manufactured by Sigma Aldrich) was used instead of Pluronic (registered trademark) F127. However, even when ultrasonic irradiation was performed, CNT could not be dispersed in the solution, and a dispersion could not be obtained.

<Result>
Table 2 shows the measurement results of the conductivity and Seebeck coefficient and the calculation results of the output factor for each measurement sample. In Example 1 in Table 2, Example 1 100 mM potassium carbonate _(K 2 CO _3, produced by Wako Pure Chemical Industries, Ltd.) in shows data for the measurement sample prepared by using a.

From Table 2, it turned out that it has the outstanding thermoelectric characteristic in any of Examples 1-4. That is, all the electrical conductivity of Examples 1-4 exceeded 1000 s / cm, all Seebeck coefficients were −20 μV / K or less, and all output factors exceeded 100 μW / mK ² .

[Evaluation of thermal stability]
About the measurement sample (when the concentration of potassium carbonate (K ₂ CO ₃ , manufactured by Wako Pure Chemical Industries, Ltd.) is 100 mM) obtained in Example 1, it is determined for a predetermined time (30 minutes, 1 minute) in an electric furnace at 100 ° C. (Time, 2 hours, 3 hours, 72 hours, 120 hours, 168 hours, 240 hours, 288 hours, 336 hours, 408 hours) After heat treatment, the conductivity and Seebeck coefficient were measured for each measurement sample.

  FIG. 4 shows the measurement results of the conductivity and Seebeck coefficient and the calculation results of the output factor for each measurement sample.

  As can be seen from FIG. 4, even after the heat treatment in an electric furnace at 100 ° C. for 400 hours, the conductivity and Seebeck coefficient of the measurement sample remained unchanged and remained constant.

  The present invention can be used in a wide variety of industries such as thermoelectric power generation systems, medical power supplies, security power supplies, and aerospace applications.

Claims (11)

A polyethylene glycol derivative, a metal cation, and an n-type nanomaterial,
The polyethylene glycol derivative has a chain structure represented by the following formula (1):
_{- (CH 2 CH 2 O)} n - ··· (1)
In formula (1), n is an integer of 4 or more.   The nanomaterial composite according to claim 1, wherein the polyethylene glycol derivative has a hydrophobic group.   The nanomaterial composite according to claim 1, wherein the polyethylene glycol derivative is a nonionic surfactant.   The nonionic surfactant is at least one selected from the group consisting of a polyoxyethylene / polyoxypropylene block polymer, a polyoxyethylene sorbitan fatty acid ester, a polyoxyethylene alkylphenyl ether, and a polyoxyethylene alkyl ether. The nanomaterial composite according to claim 3, wherein the composite is nanomaterial composite.   The nanomaterial according to any one of claims 1 to 4, wherein the n-type nanomaterial includes at least one selected from the group consisting of nanoparticles, nanotubes, nanowires, nanorods, and nanosheets. Complex.   An ink comprising the nanomaterial composite according to any one of claims 1 to 5 and a solvent. a step of bringing a polyethylene glycol derivative and a metal cation into contact with the n-type nanomaterial,
The method for producing a nanomaterial composite, wherein the polyethylene glycol derivative has a chain structure represented by the following formula (1):
_{- (CH 2 CH 2 O)} n - ··· (1)
In formula (1), n is an integer of 4 or more.   The method for producing a nanomaterial composite according to claim 7, wherein the polyethylene glycol derivative has a hydrophobic group.   The method for producing a nanomaterial composite according to claim 7 or 8, wherein the polyethylene glycol derivative is a nonionic surfactant.   The nonionic surfactant is at least one selected from the group consisting of a polyoxyethylene / polyoxypropylene block polymer, a polyoxyethylene sorbitan fatty acid ester, a polyoxyethylene alkylphenyl ether, and a polyoxyethylene alkyl ether. The method for producing a nanomaterial composite according to claim 9, wherein the nanomaterial composite is provided.   The nanomaterial according to any one of claims 7 to 10, wherein the n-type nanomaterial comprises at least one selected from the group consisting of nanoparticles, nanotubes, nanowires, nanorods and nanosheets. A method for producing a composite.

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