JP6680995B2 - Nitride thermoelectric conversion material, manufacturing method thereof, and thermoelectric conversion element - Google Patents

Description

  The present invention relates to a nitride thermoelectric conversion material suitable for a Peltier element, a Seebeck element, a thermopile, and the like, a method for producing the same, and a thermoelectric conversion element.

Conventionally, as thermoelectric materials used for thermoelectric conversion elements such as Peltier element (cooling element), Seebeck element (thermoelectric power generation element) or thermopile, BiTe-based thermoelectric material, Heusler-based thermoelectric material, clathrate thermoelectric material, oxide thermoelectric material, nitride A large number of various thermoelectric materials such as physical thermoelectric materials and thermoelectric materials made of organic materials are known. Further, development of flexible thermoelectric devices using the above materials has been actively conducted. An organic material or a printed material containing an organic material is mainly used for the flexible thermoelectric device.
Regarding these thermoelectric materials, in order to improve thermoelectric performance, a material having a large Seebeck coefficient and a large electric conductivity (small electric resistivity) and a small thermal conductivity is desired.

For example, as a nitride thermoelectric material, Patent Document 1 discloses an n-type thermoelectric conversion material containing 80 to 99% by mass of β-type silicon carbide and 1 to 10% by mass of metal nitride. An n-type thermoelectric conversion material containing 0.5 to 5 mass% of nitrogen element is described.
In Patent Document 2, the general _{formula: Al z Ga y In x M} u R v D w in _{N s} (wherein, M is a transition element, R represents a rare earth element and D respectively from Group IV or Group II element At least one element selected, 0 ≦ z ≦ 0.7, 0 ≦ y ≦ 0.7, 0.2 ≦ x ≦ 1.0, 0 ≦ u ≦ 0.7, 0 ≦ v ≦ 0.05 , 0 ≦ w ≦ 0.2 and 0.9 ≦ s ≦ 1.1, and x + y + z = 1), and the absolute value of the Seebeck coefficient at a temperature of 100 ° C. or higher is 50 μV / A nitride thermoelectric conversion material having an electric resistivity of K or more and 10 ⁻³ Ωm or less is described.

In Patent Document 3, the general _{formula: Al z Ga y In x M} u R v O s in _{N t} (wherein, M is a transition element, R is rare earth element .0 ≦ z ≦ 0.7, 0 ≦ y ≦ 0.7, 0.2 ≦ x ≦ 1.0, 0 ≦ u ≦ 0.7, 0 ≦ v ≦ 0.05, 0.9 ≦ s + t ≦ 1.7, 0.4 ≦ s ≦ A oxynitride thermoelectric conversion material having an elemental composition represented by the formula 1.2) and an absolute value of Seebeck coefficient of 40 μV / K or higher at a temperature of 100 ° C. or higher. Has been described.

Further, in Patent Document 4, a general formula: Ti _1-x A _x O _y N _z (In the formula, A is a group consisting of V, Cr, Mn, Fe, Co, Ni, Zr, and Nb, which is closer to Ti in the periodic table. At least one element selected from 0 <x ≦ 0.5; 0.5 ≦ y ≦ 2.0; 0.01 ≦ z ≦ 0.6), A thermoelectric conversion material composed of a metal oxynitride containing other unavoidable elements is described.

Furthermore, in Patent Document 5, the reaction is represented by the composition formula AE ₂ N, and the reaction between solid phase AE ₃ N ₂ and vapor of AE metal (AE is at least one element selected from Ca, Sr, and Ba) It is a nitride having a layered crystal structure composed of a product, represented by an ionic formula [AE ₂ N] ⁺ e ⁻ , having an electrical conductivity of 10 ³ S / cm or more at room temperature, and having a metallic electrical conductivity. A nitride electride showing is described.

JP 2001-274464 A Japanese Patent No. 4000366 Japanese Patent No. 4000369 Japanese Patent No. 5024745 JP, 2014-24712, A

However, even in the above-mentioned conventional technique, the following problems remain.
That is, the BiSbTe system is known as the thermoelectric material having good performance at room temperature. However, since this BiSbTe system contains harmful elements such as Bi, Sb, and Te and has a layered crystal structure, it is difficult to form a thin film on the film by sputtering. In the case of forming a thin film, there is a method of producing a BiSbTe-based ink and printing it into a printed element. However, heat treatment is required to improve the performance, and it is not easy to directly form it on a film or the like. . In addition, most thermoelectric materials made of organic materials have p-type thermoelectric characteristics, and no n-type material having good performance has been reported. Further, as the nitride-based thermoelectric material, the AlN-based, TiN-based, and CaN-based materials as described above are known, but all have a problem that they are bulk bodies and have low thermoelectric performance.

  The present invention has been made in view of the above problems, without using a harmful element, a nitride thermoelectric conversion material capable of forming a thin film such as a film and having good performance and a manufacturing method thereof and a thermoelectric conversion element. The purpose is to provide.

The present invention adopts the following configurations in order to solve the above problems. That is, the nitride thermoelectric conversion material according to the first invention has a general formula: (Cr _1-x M _x ) _1-y N _y (where M is Ti, V, Mn, Fe, Co, Ni, Cu, At least one selected from Zr, Nb, Mo, Hf, Ta, W, Si, Al, B and Y. Metal nitriding represented by 0 ≦ x <1.0, 0.40 ≦ y <0.54) It is characterized by having a crystal structure of NaCl type and having p-type or n-type thermoelectric properties.

In this nitride thermoelectric conversion material, a general formula: (Cr _1-x M _x ) _1-y N _y (where M is Ti, V, Mn, Fe, Co, Ni, Cu, Zr, Nb, Mo, Hf) , Ta, W, Si, Al, B, and Y, and at least one of them has a crystal structure of a metal nitride represented by 0 ≦ x <1.0 and 0.40 ≦ y <0.54). However, since it is an NaCl type and has p-type or n-type thermoelectric properties, it can be formed without using a harmful element and without heat treatment, has a Seebeck coefficient larger than that of an organic material system at room temperature, and has a temperature of 200 ° C. or higher. It also has high heat resistance. It should be noted that having p-type thermoelectric characteristics means that the Seebeck coefficient is positive, and having n-type thermoelectric characteristics means that the Seebeck coefficient is negative.

The nitride thermoelectric conversion material according to the second invention is characterized in that, in the first invention, x is in the range of 0 ≦ x ≦ 0.2.
That is, in this nitride thermoelectric conversion material, since x is in the range of 0 ≦ x ≦ 0.2, it is a Cr-rich nitride electronic material, and various elements are maintained while maintaining the NaCl-type CrN crystal structure. It is possible to improve the thermoelectric performance by adding a small amount of, for example, it is possible to improve the Seebeck coefficient and the electrical conductivity.

A nitride thermoelectric conversion material according to a third aspect of the present invention is, in the first or second aspect, a columnar crystal formed in a film shape and extending in a direction perpendicular to a surface of the film. And
That is, in this nitride thermoelectric conversion material, since it is a columnar crystal extending in the direction perpendicular to the surface of the film, the crystallinity of the film is high and high heat resistance is obtained.

A nitride thermoelectric conversion material according to a fourth aspect is characterized in that, in the third aspect, the columnar crystals have a crystal diameter of 100 nm or less.
That is, in this nitride thermoelectric conversion material, since the crystal diameter of the columnar crystal is 100 nm or less, it becomes difficult for the phonon (lattice) to transfer heat due to the nanoscale crystal sizing, so that the particle size is relatively large. (100 nm or more) The thermal conductivity in the in-plane direction of the thermoelectric thin film is smaller than that of the bulk sintered body material, and the in-plane temperature difference of the thermoelectric thin film can be further increased. Therefore, the thermoelectromotive force increases, and the thermoelectric performance can be improved. Also, the flexibility of the material itself can be obtained. The theoretical calculation shows that the cumulative thermal conductivity at the cut-off mean free process of 100 nm is halved in a plurality of material systems. Therefore, in the thermoelectric conversion material, the thermal conductivity can be effectively reduced by setting the particle size to 100 nm or less.

A thermoelectric conversion element according to a fifth aspect of the present invention is an insulating base material, a p-type thin film thermoelectric conversion portion and an n-type thin film thermoelectric conversion portion formed on the insulating base material, and the p-type thin film thermoelectric conversion element. A conversion electrode and a connection electrode unit that connects the n-type thin film thermoelectric conversion unit are provided, and at least one of the p-type thin film thermoelectric conversion unit and the n-type thin film thermoelectric conversion unit has first to fourth It is characterized by being formed from any of the nitride thermoelectric conversion materials of the invention.
That is, in this thermoelectric conversion element, at least one of the p-type thin film thermoelectric conversion part and the n-type thin film thermoelectric conversion part is formed of the nitride thermoelectric conversion material according to any one of the first to fourth inventions. The thin film thermoelectric conversion part having a large absolute value of Seebeck coefficient at room temperature can be used as a Peltier device, Seebeck device, thermopile, or the like having good performance.

A thermoelectric conversion element according to a sixth aspect is characterized in that, in the fifth aspect, the insulating base material is an insulating film.
That is, in this thermoelectric conversion element, since the insulating base material is an insulating film, a thin film thermoelectric conversion portion having a large Seebeck coefficient with a large absolute value is formed without heat treatment, so that the heat resistance of the resin film is low. It is possible to use a film, and it is possible to obtain a thin and flexible thermoelectric conversion element having good performance.

A method for manufacturing a nitride thermoelectric conversion material according to a seventh invention is a method for manufacturing the nitride thermoelectric conversion material according to any one of the first to fourth inventions, which is a Cr sputtering target or a Cr-M alloy sputtering target. (However, M represents at least one of Ti, V, Mn, Fe, Co, Ni, Cu, Zr, Nb, Mo, Hf, Ta, W, Si, Al, B and Y.). It is characterized by having a film forming step of performing film formation by performing reactive sputtering in a nitrogen-containing atmosphere.
That is, in this method for producing a nitride thermoelectric conversion material, a Cr sputtering target or a Cr-M alloy sputtering target (where M is Ti, V, Mn, Fe, Co, Ni, Cu, Zr, Nb, Mo, Hf, Ta, W, Si, Al, B and Y) is used to form a film by reactive sputtering in a nitrogen-containing atmosphere. Therefore, the above (Cr _1-x M _x ) _1- The nitride thermoelectric conversion material of the present invention composed of _y N _y can be deposited without heat treatment. Further, by controlling the N ₂ gas fraction at the time of sputtering, the thermoelectric performance can be controlled, and the p-type semiconductor material and the n-type semiconductor material can be produced by the same target. In addition, it is possible to fabricate an element having excellent thermoelectric performance by wiring the p-type semiconductor material and the n-type semiconductor material into wiring by a metal mask method or the like.
Furthermore, it is possible to form a film on an insulating substrate (glass, resin film) with low thermal conductivity, and since the nitride thermoelectric conversion material of the present invention also has flexibility, it can be formed on a resin film substrate. Is.

Manufacturing method of the nitride thermoelectric conversion material according to the eighth invention, in the seventh invention, the reactive sputtering carried out in a mixed gas atmosphere of Ar and N _2, with N ₂ gas fraction at this time It is characterized in that a certain N ₂ / (N ₂ + Ar) is set in the range of 0.2 to 0.5.
That is, in this method for producing a nitride thermoelectric conversion material, reactive sputtering is performed in a mixed gas atmosphere of Ar and N _2, and the N ₂ gas fraction N ₂ / (N ₂ + Ar) at this time is set. , 0.2 to 0.5, so that a nitride thermoelectric conversion material having n-type thermoelectric characteristics can be formed.

A method for manufacturing a nitride thermoelectric conversion material according to a ninth aspect is the method for manufacturing a nitride thermoelectric conversion material according to the seventh aspect, wherein the reactive sputtering is performed in a mixed gas atmosphere of Ar and N ₂ or in an N ₂ atmosphere. It is characterized in that N ₂ / (N ₂ + Ar) which is a ₂ gas fraction is set in a range of 0.6 to 1.0.
That is, in this method for producing a nitride thermoelectric conversion material, reactive sputtering is performed in a mixed gas atmosphere of Ar and N ₂ or in an N ₂ atmosphere, and the N ₂ gas fraction N ₂ / ( Since N ₂ + Ar) is set in the range of 0.6 to 1.0, a nitride thermoelectric conversion material having p-type thermoelectric characteristics can be formed.

The present invention has the following effects.
That is, according to the nitride thermoelectric conversion material of the present invention, the general formula: (Cr1 _{- xMx} ) _{1- yNy} (where M is Ti, V, Mn, Fe, Co, Ni, Cu, At least one selected from Zr, Nb, Mo, Hf, Ta, W, Si, Al, B and Y. Metal nitriding represented by 0 ≦ x <1.0, 0.40 ≦ y <0.54) It has a crystalline structure of NaCl type and has p-type or n-type thermoelectric properties, so that it can be formed without heat treatment without harmful elements and has a larger absolute value at room temperature than the organic material system. Has a coefficient.
Further, according to the method for producing a nitride thermoelectric conversion material according to the present invention, a Cr sputtering target or a Cr-M alloy sputtering target (where M is Ti, V, Mn, Fe, Co, Ni, Cu, Zr, Nb). , Mo, Hf, Ta, W , Si, Al, since the deposited performing reactive sputtering in a nitrogen containing atmosphere with a show.) at least one of B and Y, the _{(Cr 1-x} The nitride thermoelectric conversion material of the present invention composed of M _x ) _1-y N _y can be formed without heat treatment.
Furthermore, according to the thermoelectric conversion element of the present invention, at least one of the p-type thin film thermoelectric conversion part and the n-type thin film thermoelectric conversion part is the nitride thermoelectric conversion material according to any one of the first to fourth inventions. Since it is formed, a Peltier device, a Seebeck device, a thermopile, or the like having good performance can be obtained by the thin film thermoelectric conversion part having a large absolute value of Seebeck coefficient at room temperature.

1 is a perspective view showing a thermoelectric conversion element in an embodiment of a nitride thermoelectric conversion material, a method for manufacturing the same, and a thermoelectric conversion element according to the present invention. In the examples of the nitride thermoelectric conversion material, the manufacturing method thereof, and the thermoelectric conversion element according to the present invention, the nitriding amount: N / (Cr + M + N) ratio with respect to the partial pressure of nitrogen gas in CrN, CrSiN, CrTiN, CrFeN, CrYN, CrBN is shown. It is a graph. 7 is a graph showing the M (Cr + M) composition ratio in the film with respect to the target M / (Cr + M) composition ratio in the example of the present invention. 7 is a graph showing the results of X-ray diffraction (XRD) on p-type CrSiN in Examples of the present invention. 3 is a graph showing the results of X-ray diffraction (XRD) on n-type CrSiN in Examples of the present invention. 3 is a graph showing the results of X-ray diffraction (XRD) on p-type CrTiN in Examples of the present invention. 3 is a graph showing the results of X-ray diffraction (XRD) on n-type CrTiN in Examples of the present invention. In an example concerning the present invention, it is a section SEM photograph in p-type CrSiN. In the Example which concerns on this invention, it is a cross-section SEM photograph in n type CrSiN. 3 is an SEM photograph of a cross section of p-type CrTiN in an example according to the present invention. In an example concerning the present invention, it is a section SEM photograph in n type CrTiN. 7 is a graph showing the relationship between temperature and Seebeck coefficient in p-type CrN, CrSiN, CrTiN, CrFeN, and CrWN in Examples according to the present invention. 3 is a graph showing the relationship between the temperature and Seebeck coefficient in n-type CrN, CrSiN, and CrTiN in the example according to the present invention. 3 is a graph showing the relationship between temperature and electrical conductivity in p-type CrN, CrSiN, CrTiN, CrFeN, CrWN in Examples according to the present invention. 3 is a graph showing a relationship between temperature and electrical conductivity in n-type CrN, CrSiN, and CrTiN in Examples according to the present invention.

  Hereinafter, an embodiment of a nitride thermoelectric conversion material, a method for producing the same, and a thermoelectric conversion element according to the present invention will be described with reference to FIG. In the drawings used in the following description, the scale is appropriately changed as necessary in order to make each unit recognizable or easily recognizable.

The nitride thermoelectric conversion material of the present embodiment has a general formula: (Cr _1-x M _x ) _1-y N _y (where M is Ti, V, Mn, Fe, Co, Ni, Cu, Zr, Nb, At least one of Mo, Hf, Ta, W, Si, Al, B and Y is shown, which is made of a metal nitride represented by 0 ≦ x <1.0 and 0.40 ≦ y <0.54), Its crystal structure is a cubic NaCl type (space group Fm-3m (No. 225)) and has p-type or n-type thermoelectric properties. Oxygen is contained as an unavoidable impurity.
Although Cr ₂ N is a bulk CrN-based material, its crystal structure is a hexagonal space group P-31m (No. 162), and its crystal structure is different from that of the present nitride thermoelectric conversion material. .

The nitride thermoelectric conversion material is a columnar crystal formed in a film shape and extending in a direction perpendicular to the surface of the film. Further, the crystal diameter of the columnar crystal is 100 nm or less.
The thin film of the nitride thermoelectric conversion material has excellent [111] crystal orientation in the direction perpendicular to the substrate.

  Next, a thermoelectric conversion element using the nitride thermoelectric conversion material of this embodiment will be described. As shown in FIG. 1, the thermoelectric conversion element 1 includes an insulating base material 2, a p-type thin film thermoelectric conversion portion 3p and an n-type thin film thermoelectric conversion portion 3n formed on the insulating base material 2. , A p-type thin film thermoelectric converter 3p and an n-type thin film thermoelectric converter 3n are connected to each other, and the connected p-type thin film thermoelectric converter 3p and n-type thin film thermoelectric converter 3n are connected. It is provided with a pair of electrode terminal portions 5 formed at the ends.

At least one of the p-type thin film thermoelectric conversion portion 3p and the n-type thin film thermoelectric conversion portion 3n is formed of the nitride thermoelectric conversion material.
In the present embodiment, both the p-type thin film thermoelectric conversion portion 3p and the n-type thin film thermoelectric conversion portion 3n are formed of the above-mentioned nitride thermoelectric conversion material of the present invention. May be formed of an organic thermoelectric material (printed material), and the n-type thin film thermoelectric conversion portion 3n may be formed of the nitride thermoelectric conversion material of the present invention.

  The p-type thin film thermoelectric conversion unit 3p and the n-type thin film thermoelectric conversion unit 3n are formed in a plurality of linear shapes or strip shapes, extend in parallel with each other, and are arranged alternately. In addition, the end portions of the p-type thin film thermoelectric conversion portion 3p and the n-type thin film thermoelectric conversion portion 3n which are adjacent to each other are connected by the connection electrode portion 4, and a single thin film thermoelectric conversion portion in which the whole is folded back a plurality of times And a pair of electrode terminal portions 5 are formed at both ends.

The connection electrode portion 4 and the electrode terminal portion 5 are pattern-formed with Ag, Ag alloy or the like.
A lead wire 6 is connected to the pair of electrode terminal portions 5, and the lead wire 6 is connected to a power supply 7.

  The insulating base material 2 is preferably formed of a material having a low thermal conductivity, and for example, an insulating film or glass can be adopted. As the insulating film, for example, a film formed of a polyimide resin sheet is used. The insulating film may be LCP: liquid crystal polymer, PET: polyethylene terephthalate, PEN: polyethylene naphthalate, or the like. Further, as the glass substrate, for example, non-alkali glass, alkali glass plate, glass film or the like can be adopted.

  When an insulating film is used as the insulating base material 2, the sheet-type thermoelectric conversion element 1 is obtained. For example, a sheet-type Peltier element (cooling element) that converts electrical energy into heat energy and performs heat transport, a sheet-type Seebeck element (thermoelectric power generation element) that converts thermal energy into electrical energy, and performs temperature difference power generation, A sheet-type thermopile or the like that serves as an infrared sensor that applies the principle of a thermocouple can be used.

The method for manufacturing the nitride thermoelectric conversion material will be described below.
First, a method for manufacturing a nitride thermoelectric conversion material according to the present embodiment uses a Cr sputtering target or a Cr-M alloy sputtering target (where M is Ti, V, Mn, Fe, Co, Ni, Cu, Zr, Nb, Mo). , Hf, Ta, W, Si, Al, B, and Y) is used to form a film by reactive sputtering in a nitrogen-containing atmosphere.

For example, when x = 0 (when the element M is not included), a Cr sputtering target is used, when M = Ti, a Cr-Ti alloy sputtering target is used, and when M = V, a Cr- A V alloy sputtering target is used, a Cr—Mn alloy sputtering target is used when M = Mn, and a Cr—Fe alloy sputtering target is used when M = Fe.
When M = Co, a Cr—Co alloy sputtering target is used, when M = Ni, a Cr—Ni alloy sputtering target is used, and when M = Cu, a Cr—Cu alloy sputtering target is used. When M = Zr, a Cr-Zr alloy sputtering target is used, and when M = Nb, a Cr-Nb alloy sputtering target is used.
When M = Mo, a Cr-Mo alloy sputtering target is used, when M = Hf, a Cr-Hf alloy sputtering target is used, and when M = Ta, a Cr-Ta alloy sputtering target is used. When M = W, a Cr-W alloy sputtering target is used, and when M = Si, a Cr-Si alloy sputtering target is used.
Further, when M = Al, a Cr-Al alloy sputtering target is used, when M = B, a Cr-B alloy sputtering target is used, and when M = Y, a Cr-Y alloy sputtering target is used. .

In the film forming step, the case of manufacturing the n-type nitride thermoelectric conversion material, in the reactive sputtering carried out in a mixed gas atmosphere of Ar and N _2, N ₂ is N ₂ gas fraction at this time / (N ₂ + Ar) is set in the range of 0.2 to 0.5.
In the case of producing a p-type nitride thermoelectric conversion material, the reactive sputtering is performed in a mixed gas atmosphere of Ar and N ₂ or in an N ₂ atmosphere, and the N ₂ gas fraction N ₂ / (N ₂ + Ar) is set in the range of 0.6 to 1.0.
The reactive sputtering is performed in a mixed gas atmosphere of Ar and N _2, and the N ₂ gas fraction N ₂ / (N ₂ + Ar) at this time is in the range of 0.5 to 0.6. Even if it is set to, a p-type or n-type nitride thermoelectric conversion material can be produced, but the N ₂ gas fraction that becomes the boundary between p-type and n-type differs depending on the composition.
The connection electrode part 4 and the electrode terminal part 5 are patterned by a metal mask method.

Thus, in the nitride thermoelectric conversion material of the present embodiment, the general formula: (Cr1 _{- xMx} ) _{1- yNy} (where M is Ti, V, Mn, Fe, Co, Ni, Cu, Zr). , Nb, Mo, Hf, Ta, W, Si, Al, B, and Y, and at least one metal nitride represented by 0 ≦ x <1.0 and 0.40 ≦ y <0.54). Since its crystal structure is NaCl type and has p-type or n-type thermoelectric properties, it can be formed without heat treatment without harmful elements and has a Seebeck coefficient larger than that of organic material system at room temperature. Moreover, it also has high heat resistance of 200 ° C. or higher.

Further, when x is in the range of 0 ≦ x ≦ 0.2, it becomes Cr-rich and becomes a Cr-rich nitride electronic material. Therefore, a small amount of various elements are added while maintaining the NaCl-type CrN crystal structure. By doing so, the thermoelectric performance can be improved, and the Seebeck coefficient and the electric conductivity can be improved.
Further, since the columnar crystals extend in the direction perpendicular to the surface of the film, the film has high crystallinity and high heat resistance.

  Furthermore, since the crystal diameter of the columnar crystal is 100 nm or less, it becomes difficult for the heat due to the phonons (lattice) to be transmitted due to the nanoscale crystal sizing, and thus the bulk sintered body having a relatively large particle size (100 nm or more). The thermal conductivity in the in-plane direction of the thermoelectric thin film is smaller than that of the material, and the in-plane temperature difference of the thermoelectric thin film can be further increased. Therefore, the thermoelectromotive force increases, and the thermoelectric performance can be improved. Also, the flexibility of the material itself can be obtained.

  In the thermoelectric conversion element 1 of the present embodiment, at least one of the p-type thin film thermoelectric conversion portion 3p and the n-type thin film thermoelectric conversion portion 3n is formed of the above-mentioned nitride thermoelectric conversion material. Due to the large thin film thermoelectric conversion units 3p and 3n, a Peltier device, a Seebeck device, a thermopile, or the like having good performance can be obtained.

In the method for manufacturing the nitride thermoelectric conversion material of the present embodiment, a Cr sputtering target or a Cr-M alloy sputtering target (where M is Ti, V, Mn, Fe, Co, Ni, Cu, Zr, Nb, Mo, Hf) is used. , Ta, W, Si, Al, B, and Y) are used to form a film by performing reactive sputtering in a nitrogen-containing atmosphere, the above (Cr _1-x M _x ) ₁ the nitride thermoelectric conversion material of the present invention comprising _-y N _y can be deposited without heat treatment.

Further, by controlling the N ₂ gas fraction at the time of sputtering, the thermoelectric performance can be controlled, and the p-type semiconductor material and the n-type semiconductor material can be produced by the same target. In addition, it is possible to fabricate an element having excellent thermoelectric performance by wiring the p-type semiconductor material and the n-type semiconductor material into wiring by a metal mask method or the like.
Furthermore, it is possible to form a film on an insulating substrate (glass, resin film) with low thermal conductivity, and since the nitride thermoelectric conversion material of the present invention also has flexibility, it can be formed on a resin film substrate. Is.

That is, reactive sputtering is performed in a mixed gas atmosphere of Ar and N _2, and the N ₂ gas fraction N ₂ / (N ₂ + Ar) at this time is set in the range of 0.2 to 0.5. By setting, a nitride thermoelectric conversion material having n-type thermoelectric properties can be formed.
In addition, the reactive sputtering is performed in a mixed gas atmosphere of Ar and N ₂ or in an N ₂ atmosphere, and the N ₂ gas fraction N ₂ / (N ₂ + Ar) at this time is 0.6 to 1 By setting it in the range of 0.0, it is possible to form a nitride thermoelectric conversion material having n-type thermoelectric characteristics.

  Next, the nitride thermoelectric conversion material, the method for manufacturing the same, and the thermoelectric conversion element according to the present invention were evaluated by the examples produced based on the above-described embodiments, and the results are specifically described with reference to FIGS. 2 to 15. explain.

First, as shown in Table 1 and Table 2 by the reactive sputtering method, a Cr sputtering target or a Cr-M alloy sputtering target having a composition of "M / (Cr + M) ratio" (atomic%) and alkali-free glass The nitride thermoelectric conversion material of the present invention formed in various composition ratios was formed on the substrate to have a thickness of 400 to 600 nm. The film thickness was measured by a surface shape measuring device: Dektak 150 manufactured by Veeco.
Some samples were also formed on a polyimide film substrate.

For comparison, a printed thin film of Bi ₂ Te ₃ (Comparative Example 1), a Cr thin film (Comparative Example 2) and a TiN thin film (Comparative Example 3) were prepared, and these Comparative Examples were similarly prepared and evaluated. went.
The printed thin film of Bi ₂ Te ₃ of Comparative Example 1 was prepared as follows. Bi ₂ Te ₃ fine powder was mixed with ethylene glycol and a dispersant to obtain a Bi ₂ Te ₃ paste. Bi ₂ Te ₃ having a film thickness of about 1 micron was wired on a liquid crystal polymer (LCP) substrate by a dispenser, dried, and then heat-treated at 200 ° C. in an N ₂ atmosphere. This sample was found to be in close contact with the film, and after evaluation, it was confirmed by SEM that there were no cracks.
The Cr thin film of Comparative Example 2 and the TiN thin film of Comparative Example 3 were formed by a reactive sputtering method using a Cr target and a Ti target, respectively.

In addition, the sputtering conditions of the film forming process are as follows: ultimate vacuum: 5 × 10 ⁻⁶ Pa, sputtering gas pressure: 0.67 Pa, target input power (output): 300 W, in a mixed gas atmosphere of Ar gas and nitrogen gas. , And the partial pressure of nitrogen gas was changed to 0 to 100%.
Further, a pair of Ag electrodes were pattern-formed by a metal mask method on the formed thin film of the above-mentioned nitride thermoelectric conversion material to prepare Examples and Comparative Examples of the present invention.

<Composition analysis>
The composition of the nitride thermoelectric conversion material obtained by the reactive sputtering method was analyzed by EPMA (Electron Probe Micro Analyzer). This EPMA analysis was performed under the accelerating voltage of 8 kV. The spectral overlap between the L line of Ti and the Kα line of N in the material containing Ti was intensity-separated by the interference correction method.
FIG. 2 shows the results of examining the nitriding amount: N / (Cr + M + N) ratio with respect to the partial pressure of nitrogen gas for CrN, CrTiN, CrSiN, CrFeN, CrYN, and CrBN. The quantitative accuracy of N / (Cr + M + N) is 2%.
In the range of N ₂ gas fraction 0.2 to 0.5 showing n-type thermoelectric characteristics, 0.40 ≦ N / (Cr + M + N) <0.52, and N ₂ gas fraction 0 showing p-type thermoelectric characteristics is 0. In the range of 0.6 to 1.0, 0.51 ≦ N / (Cr + M + N) <0.54. It is considered that the p-type material has a larger amount of nitriding and a smaller amount of nitrogen defects than the n-type material.
It has been confirmed that the M / (Cr + M) ratio is substantially the same as the M / (Cr + M) ratio composition of the target as shown in FIG.

In the 400-600 nm-thick EPMA analysis, it is uncertain whether oxygen is derived from the glass substrate or oxygen contained in the nitride film. Therefore, some samples are also subjected to elemental analysis by X-ray photoelectron spectroscopy (XPS). It was In this XPS, quantitative analysis was carried out on the sputter surfaces having a depth of 20 nm, 60 nm, and 100 nm from the outermost surface by Ar sputtering. It has been confirmed that the M / (Cr + M) ratios on the sputter surfaces with depths of 20 nm, 60 nm, and 100 nm have the same M / (Cr + M) composition ratio within the range of quantitative accuracy.
In the above X-ray photoelectron spectroscopy (XPS), AlKα (350 W) was used as the X-ray source, pass energy: 46.95 eV, measurement interval: 0.1 eV, photoelectron extraction angle with respect to the sample surface: 45 deg, and analysis area was about Quantitative analysis was performed under the condition of 800 μmφ.
As a result, in all the samples, the oxygen ratio O / (Cr + M + N + O) was 0 <O / (Cr + M + N + O) <0.05, indicating that oxygen was contained as an unavoidable impurity.
However, since there is no correlation between the thermoelectric properties (Seebeck coefficient, electric conductivity) and the amount of oxygen, oxygen does not actively contribute to the thermoelectric properties, and it is considered that the present thermoelectric properties are mainly metal nitrides. .

<Thin film X-ray diffraction (identification of crystal phase)>
The crystal phase of the nitride thermoelectric conversion material obtained by the reactive sputtering method was identified by grazing incidence X-ray diffraction. This thin film X-ray diffraction was a micro-angle X-ray diffraction experiment, and the tube was made of Cu, the incident angle was 1 degree, and the measurement was performed in the range of 2θ = 20 to 130 degrees. With respect to some samples, the incident angle was set to 0 degree, and measurement was performed in the range of 2θ = 20 to 100 degrees.

As a result, in all the examples of the present invention, the crystal structure was a cubic type NaCl type (space group Fm-3m (No. 225)) and was a material excellent in [111] crystal orientation.
Cr ₂ N is a bulk CrN-based material, but its crystal structure is hexagonal space group P-31m (No. 162), which is different from the present nitride thermoelectric conversion material in crystal structure. ing.
Regarding Example 7 (p-type CrSiN), Example 5 (n-type CrSiN), Example 18 (p-type CrTiN), and Example 16 (n-type CrTiN), as examples of XRD profiles. 4 to 7.

<Performance evaluation>
Next, the Seebeck coefficient S, the electrical conductivity σ, and the power factor (power factor: S ² σ) were evaluated for the examples and comparative examples of the present invention. The Seebeck coefficient and electric conductivity were measured at room temperature.
For the Seebeck coefficient, two commercially available Peltier elements are used, and wiring is performed so that one Peltier element is cooled and the other Peltier element is heated so that there is a temperature difference between the two Peltier elements. The temperature difference was measured. A 0.15 mmΦ sheath thermocouple (Sakaguchi Electrothermal T350155 sheath material: Pt, sheath filling: MgO powder) was used to measure the thermoelectromotive force using the sheath as an electrode, and a temperature difference was also measured using the thermocouple. It was measured. The Seebeck coefficient was evaluated by linearly approximating the obtained relationship between the thermoelectromotive force and the temperature difference by the least square method. The electric conductivity was measured by the Van der Pauw method.

Next, it was determined from the Seebeck coefficient whether it was a p-type semiconductor material or an n-type semiconductor material. As a result, the embodiment in which the N ₂ gas fraction (gas ratio) N ₂ / (N ₂ + Ar) is in the range of 0.2 to 0.5 has n-type thermoelectric properties, and N ₂ In the examples in which / (N ₂ + Ar) was in the range of 0.6 to 1.0, p-type thermoelectric properties were obtained.
In addition, as a result of examining the electric conductivity, almost all of the n-type material and the p-type material had a high electric conductivity of 10 S / cm or more. Particularly, some of the samples had an extremely high electric conductivity of 1000 S / cm or more.
As a result, in each of the examples of the present invention, the absolute value of the Seebeck coefficient was relatively large and the electrical conductivity was good. Moreover, the Seebeck coefficient was changed by controlling the N ₂ gas fraction during sputtering, and the thermoelectric performance could be controlled using the same target.

<Evaluation of crystal form>
Next, as an example showing the crystal morphology in the cross section of the nitride thermoelectric conversion material, Example 7 (p-type CrSiN), Example 5 (n-type CrSiN), Example 18 (p-type CrTiN), and Example. SEM photographs of cross sections with 16 (n-type CrTiN) are shown in FIGS. 8 to 11.
The samples of these examples are cleaved. In addition, it is a photograph observed by tilting at an angle of 45 °.

As can be seen from these photographs, the examples of the present invention are formed of dense columnar crystals. That is, it is observed that columnar crystals grow in the direction perpendicular to the substrate surface. The breakage of the columnar crystals occurred when the cleavage break occurred.
The grain size (crystal diameter) of the columnar crystals in the photographs was 100 nm or less.

The grain size here is the diameter of the columnar crystal in the plane of the substrate, and the length is the length (film thickness) of the columnar crystal in the direction perpendicular to the plane of the substrate.
If the aspect ratio of the columnar crystal is defined as (length) ÷ (grain size), this embodiment has a large aspect ratio of 5 or more. It is considered that the film is dense due to the small grain size of the columnar crystals.

<Heat resistance>
For each example, the temperature dependence of the Seebeck coefficient was evaluated. The results are shown in FIG. 12 for the p-type nitride thermoelectric conversion material (Examples 3, 7, 18, 34, 50) and also for the n-type nitride thermoelectric conversion material (Examples 1, 10, 21). ) Is shown in FIG.
Next, for each example, the temperature dependence of the electrical conductivity was evaluated. The results are shown in FIG. 14 for the p-type nitride thermoelectric conversion material (Examples 3, 7, 18, 34, 50) and also for the n-type nitride thermoelectric conversion material (Examples 1, 10, 21). ) Is shown in FIG.
From these results, it can be seen that in the examples of the present invention, both n-type and p-type have heat resistance of 200 ° C. Regarding the Seebeck coefficient, in both the n-type and the p-type, the absolute value of the Seebeck coefficient tended to increase with increasing temperature. Regarding the electrical conductivity, both the n-type and p-type materials tended to exponentially increase with increasing temperature. Therefore, it can be seen that the nitride thermoelectric conversion material of the present invention having n-type and p-type characteristics has improved thermoelectric characteristics as the temperature rises.

<Thermal conductivity in the film thickness direction>
Next, the nitride thermoelectric conversion material of the present invention was formed on a glass substrate, and the thermal conductivity of the thin film in the film thickness direction was measured using the picosecond thermoreflectance method.
First, a nitride thermoelectric conversion material of the present invention (the same material as in Example 28) was deposited on a glass substrate in a thickness of 1246 nm, and a Mo film was deposited in a thickness of 100 nm as a reflective film to prepare an evaluation sample. This evaluation sample was subjected to surface heating and temperature measurement by the pulsed light heating thermoreflectance method.

The time constant and the temperature amplitude coefficient were obtained from the obtained temperature history curve, and the thermal effusivity in the film thickness direction of the thin film was measured. Further, the thermal conductivity was calculated based on the obtained thermal effusivity, specific heat capacity and density. At this time, the specific heat capacity and the density were based on the values of bulk (Cr ₂ N, VN). The thermal conductivity value is an estimated value calculated by substituting the specific heat capacity and density of a bulk material having the same composition as the thin film, but the thermal diffusivity is sensitive to the crystal structure and microstructure of the thin film. However, since the specific heat capacity and the density do not depend much on the crystal structure and the microstructure, it is considered that the difference from the bulk value is not so large for a dense thin film.

As a result, in the evaluation sample of the present invention (the same material as in Example 28), the thermal conductivity in the film thickness direction at room temperature was 6.2 W / (m · K).
Note that the thermal conductivity evaluation in this embodiment was in the film thickness direction in which the film was deposited at 1246 nm, but in the in-plane direction constituted by columnar crystals of 100 nm or less, a decrease in thermal conductivity due to phonons (lattice) is expected. Therefore, it is estimated that the thermal conductivity is smaller than 6.2 W / (m · K).

Further, the performance index: ZT value was evaluated for this evaluation sample (the same material as in Example 28). The Seebeck coefficient and electric conductivity were evaluated in the in-plane direction, and the thermal conductivity was evaluated in the film thickness direction. As a result, the ZT value at room temperature (25 ° C.) was 0.004.
The ZT value is defined by the following formula.
ZT = (S ² σ / κ) · T
(S: Seebeck coefficient, σ: electrical conductivity, κ: thermal conductivity, T: temperature)

  The technical scope of the present invention is not limited to the above-described embodiments and examples, and various modifications can be made without departing from the spirit of the present invention.

  DESCRIPTION OF SYMBOLS 1 ... Thermoelectric conversion element, 2 ... Insulating base material, 3p ... P-type thin film thermoelectric conversion part, 3n ... N-type thin film thermoelectric conversion part, 4 ... Connection electrode part, 5 ... Electrode terminal part

Claims (8)

General _{formula: (Cr 1-x M x} ) 1-y N y ( where, M represents Ti, V, Mn, Fe, Co, Mo, W, Si, Al, at least one of B and Y. 0 ≦ x <1.0, 0.40 ≦ y <0.54), and
Its crystal structure is NaCl type and has p-type or n-type thermoelectric properties,
Formed into a film,
Ri columnar crystals der extending in a direction perpendicular to the surface of said membrane,
The nitride thermoelectric conversion material , wherein x is in the range of 0 ≦ x ≦ 0.2 . The nitride thermoelectric conversion material according to claim 1 ,
The nitride thermoelectric conversion material, wherein the crystal diameter of the columnar crystal is 100 nm or less. An insulating base material,
A p-type thin film thermoelectric conversion part and an n-type thin film thermoelectric conversion part formed on the insulating base material;
A p-type thin film thermoelectric conversion part and a connection electrode part for connecting the n-type thin film thermoelectric conversion part;
At least one of the said p-type thin film thermoelectric conversion part and the said n-type thin film thermoelectric conversion part is formed by the nitride thermoelectric conversion material of Claim 1 or 2 , The thermoelectric conversion element characterized by the above-mentioned. The thermoelectric conversion element according to claim 3 ,
The thermoelectric conversion element, wherein the insulating base material is an insulating film. A method of manufacturing a nitride thermoelectric conversion material according to claim 1 or 2,
Using a Cr sputtering target or a Cr-M alloy sputtering target (where M represents at least one of Ti, V, Mn, Fe, Co , Mo , W, Si, Al, B and Y) and containing nitrogen. A method for producing a nitride thermoelectric conversion material, comprising a film forming step of forming a film by performing reactive sputtering in an atmosphere. The method for producing a nitride thermoelectric conversion material according to claim 5 ,
The reactive sputtering is performed in a mixed gas atmosphere of Ar and N ₂ or in a N ₂ atmosphere, and the N ₂ gas fraction N ₂ / (N ₂ + Ar) at this time is 0.2 or more. A method for producing a nitride thermoelectric conversion material, which is set to a range of 0 or less. The method for producing a nitride thermoelectric conversion material according to claim 6 ,
The method for producing a nitride thermoelectric conversion material, wherein the N ₂ gas fraction is set in a range of 0.2 or more and 0.5 or less. The method for producing a nitride thermoelectric conversion material according to claim 6 ,
The method for producing a nitride thermoelectric conversion material, wherein the N ₂ gas fraction is set in a range of 0.6 or more and 1.0 or less.