JP6791733B2 - Iron Nitride Particles and Method for Producing Iron Nitride Particles - Google Patents

Description

The present invention relates to iron nitride particles and a method for producing iron nitride particles.

Α ″ -Fe ₁₆ N ₂ is known as a magnetic material having extremely high saturation magnetization and excellent magnetic properties. The iron nitride material containing α''-Fe ₁₆ N ₂ is used as a raw material for a magnetic member such as a magnetic recording medium. A typical example is a tape-like particle obtained by mixing nanoparticles having a particle size of nano-order α''-Fe ₁₆ N ₂ with a binder such as a resin or an organic substance and applying the mixture to a support film.

Various methods for producing an iron nitride material containing α''-Fe ₁₆ N ₂ have been studied so far.
For example, in Patent Document 1, agglomerated particles of iron oxide or iron oxyhydroxide as a starting material are pulverized and dispersed by a ball mill or the like, and the obtained iron compound powder is hydrogen-reduced and then subjected to a nitriding treatment. A method for producing iron nitride powder (Fe ₁₆ N ₂ ) is described in.
Further, Non-Patent Document 1 describes a method for forming an iron nitride layer by a molecular beam epitaxy method. Non-Patent Document 2 describes a method of forming an iron nitride layer by a sputtering method.

International Publication No. 2012/099202

M. Komuro et al. , "Epitical growth and magnetic flux of Fe16N2 films with high saturation magnetic flux density (invited)" Journal ofPlys. 67, No. 9, pp. 5126-5130 M. Takahashi et al. , "Magnetic Moment of α"-Fe16N2 films (invited) "Journal of Applied Physics, 1994, vol. 76, No. 10, pp. 6642-6647

The method described in Patent Document 1 has a problem that the number of steps is large, it is complicated, and it takes time. That is, since α''-Fe ₁₆ N ₂ becomes unstable at a high temperature exceeding 250 ° C., the nitriding treatment needs to be performed at a low temperature (130 ° C. to 170 ° C.). In order to nitride the Fe powder at such a temperature, it is required to increase the reaction area and reduce the diffusion distance of N in Fe, so Fe needs to be nanoparticles. Since Fe nanoparticles are easily oxidized, they must be prepared by reducing them from the Fe compound in a reducing atmosphere. Further, if the iron compound powder such as iron oxide is not subjected to the dispersion treatment before the reduction treatment, strong aggregates are formed by the reduction treatment at 400 ° C. to 600 ° C. As described above, the method described in Patent Document 1 cannot directly obtain iron nitride particles containing α''-Fe ₁₆ N ₂ at a high concentration, and requires many steps.
Further, in the iron nitride particles containing α''-Fe ₁₆ N ₂ produced by the method described in Cited Document 1, FeO is formed on the outer shell of the particles. It is said that this is because the iron metal portion from which nitrogen has been removed only at the particle surface interface is oxidized after the nitriding treatment.

The method described in Non-Patent Document 1 and Non-Patent Document 2 is a method for producing a film-shaped α ″ -Fe ₁₆ N ₂ , and cannot obtain a particulate α ″ -Fe ₁₆ N ₂ . In addition, it takes time to form a film, and since an environment such as vacuum is required, continuous processing is difficult, and it is not suitable for industrial production.

Therefore, an object of the present invention is to provide iron nitride particles containing α''-Fe ₁₆ N ₂ at a high concentration. Furthermore, it is an object of the present invention to provide a method for producing iron nitride particles capable of easily producing the iron nitride particles in a relatively short time.

The method for producing iron nitride particles according to one aspect of the present invention is
The average particle size is 10 nm or more and 10 μm or less, the content of α''-Fe ₁₆ N ₂ is 30% by mass or more, the iron nitride particles have an anticorrosion layer on the surface, and the anticorrosion layer is ε-Fe. A method for producing iron nitride particles that are _2-3 N or iron carbide .
By providing iron having a purity of 99% by mass or more as an anode and a nitrogen gas reducing electrode as a cathode in the molten salt and performing molten salt electrolysis, the content of α''-Fe ₁₆ N _{2 in} the molten salt Has an electrolysis step of precipitating iron nitride particles in an amount of 30% by mass or more.
In the electrolysis step, the temperature of the molten salt is 250 ° C. or lower.
After the electrolysis step, there is an anticorrosion layer forming step of forming an anticorrosion layer on the surface of the iron nitride particles.
The anticorrosion layer is ε-Fe _2-3N or iron carbide.
This is a method for producing iron nitride particles.

According to the above invention, it is possible to provide iron nitride particles containing α''-Fe ₁₆ N ₂ at a high concentration. Furthermore, it is possible to provide a method for producing iron nitride particles, which can easily produce the iron nitride particles in a relatively short time.

It is a figure which shows the outline of an example of the electrolysis process in the manufacturing method of iron nitride particles which concerns on embodiment of this invention. It is a figure which shows the outline of an example of the structure of the nitrogen gas reduction electrode which can be used in the electrolysis step in the manufacturing method of iron nitride particles which concerns on embodiment of this invention. It is a figure which shows the outline of another example of the structure of the nitrogen gas reduction electrode which can be used in the electrolysis step in the manufacturing method of iron nitride particles which concerns on embodiment of this invention. It is a figure which shows the outline of still another example of the structure of the nitrogen gas reduction electrode which can be used in the electrolysis step in the manufacturing method of iron nitride particles which concerns on embodiment of this invention. It is a figure which shows the outline of still another example of the structure of the nitrogen gas reduction electrode which can be used in the electrolysis step in the manufacturing method of iron nitride particles which concerns on embodiment of this invention.

[Explanation of Embodiments of the Present Invention]
First, embodiments of the present invention will be listed and described.
(1) The iron nitride particles according to one aspect of the present invention are
Iron nitride particles having an average particle size of 10 nm or more and 10 μm or less and an α ″ -Fe ₁₆ N ₂ content of 30% by mass or more.
According to the aspect of the invention described in (1) above, iron nitride particles containing α''-Fe ₁₆ N ₂ at a high concentration can be provided.

(2) The iron nitride particles according to (1) above preferably have an anticorrosion layer on the surface.
(3) The anticorrosion layer according to (2) above is preferably ε-Fe _2-3N , iron carbide or iron oxide.
According to the aspect of the invention described in (2) or (3) above, it is possible to provide iron nitride particles that are not easily affected by the atmosphere such as the atmosphere and are not easily deteriorated.

(4) The method for producing iron nitride particles according to one aspect of the present invention is
The method for producing iron nitride particles according to (1) above.
By providing iron having a purity of 99% by mass or more as an anode and a nitrogen gas reducing electrode as a cathode in the molten salt and performing molten salt electrolysis, the content of α''-Fe ₁₆ N _{2 in} the molten salt Has an electrolysis step of precipitating iron nitride particles in an amount of 30% by mass or more.
A method for producing iron nitride particles in which the temperature of the molten salt is 250 ° C. or lower in the electrolysis step.
According to the aspect of the invention described in (4) above, it is possible to provide a method for producing iron nitride particles containing α''-Fe ₁₆ N ₂ at a high concentration.

(5) The method for producing iron nitride particles according to (4) above is
In the electrolysis step, the potential applied to the anode is preferably 0.5 V or more and 3.5 V or less based on Li ⁺ / Li.
According to the aspect of the invention described in (5) above, it is possible to provide a method for producing iron nitride particles, which can easily produce iron nitride particles in a relatively short time.

(6) The method for producing iron nitride particles according to the above (4) or (5) is described.
Prior to the electrolysis step, it is preferable to have a preparatory step for dissolving the nitride ion (N ^3- ) in the molten salt.
According to the aspect of the invention described in (6) above, the α ″ -Fe ₁₆ N ₂ particles can be rapidly precipitated in the electrolysis step.

(7) The method for producing iron nitride particles according to any one of (4) to (6) above is
After the electrolysis step, it is preferable to have an anticorrosion layer forming step of forming an anticorrosion layer on the surface of the iron nitride particles.
(8) The method for producing iron nitride particles according to (7) above is
The anticorrosion layer is preferably ε-Fe _2-3 N, iron carbide or iron oxide.
According to the aspect of the invention described in (7) or (8) above, it is possible to provide a method for producing iron nitride particles that are not easily affected by the atmosphere such as the atmosphere and are not easily deteriorated.

(9) The method for producing iron nitride particles according to any one of (4) to (8) above is
It is preferable that the molten salt is a halide of an alkali metal, a halide of an alkaline earth metal, or a mixture thereof.
(10) The method for producing iron nitride particles according to (9) above is
The alkali metal halide is preferably an alkali metal bromide, iodide or a mixture of bromide and iodide.
(11) The method for producing iron nitride particles according to the above (9) or (10) is described.
The halide of the alkaline earth metal is preferably a bromide of the alkaline earth metal, iodide or a mixture of bromide and iodide.
(12) The method for producing iron nitride particles according to any one of (9) to (11) above
It is preferable that the alkali metal is at least one selected from the group consisting of Li, K and Cs.
(13) The method for producing iron nitride particles according to any one of (9) to (12) above is described.
It is preferable that the alkaline earth metal is at least one selected from the group consisting of Mg, Ca, Sr and Ba.
(14) The method for producing iron nitride particles according to any one of (4) to (13) above is described.
The molten salt is preferably LiBr-KBr-CsBr or LiI-KI-CsI.
(15) The method for producing iron nitride particles according to any one of (4) to (14) above is described.
The molten salt contains Li ⁺ , K ⁺ and Cs ^+, and the content of Li ⁺ is 40 mol% or more and 80 mol% or less, the content of K ⁺ is 5 mol% or more and 30 mol% or less, and the content of Cs ⁺ is It is preferably 10 mol% or more and 40 mol% or less.
According to the aspect of the invention according to any one of the above (9) to (15), it is relatively easy to obtain a molten salt in a temperature range in which α''-Fe ₁₆ N ₂ is stable. In addition, it can be formed by a material type that is easy to handle.

[Details of Embodiments of the present invention]
Specific examples of the iron nitride particles and the method for producing the iron nitride particles according to the embodiment of the present invention will be described below. It should be noted that the present invention is not limited to these examples, and is indicated by the scope of claims, and is intended to include all modifications within the meaning and scope equivalent to the scope of claims.

<Iron nitride particles>
The iron nitride particles according to the embodiment of the present invention have an α''-Fe ₁₆ N ₂ content of 30% by mass or more. When the content of α''-Fe ₁₆ N ₂ is 30% by mass or more, the characteristics of α''-Fe ₁₆ N ₂ having high saturation magnetization can be sufficiently exhibited. The higher the content of α''-Fe ₁₆ N ₂ is, the more preferable it is, more preferably 50% by mass or more, and further preferably 80% by mass or more.
The iron nitride particles may intentionally or unavoidably contain components other than α''-Fe ₁₆ N ₂ . As the components other than α''-Fe ₁₆ N ₂ , for example, Fe, Fe ₄ N, Fe ₃ N, FeO, Fe ₂ O ₃ , Fe ₃ O ₄ , FeOH and the like may be contained.

The iron nitride particles according to the embodiment of the present invention have an average particle size of 10 nm or more and 10 μm or less. When the average particle size of the iron nitride particles is 10 nm or more, a desired coercive force can be obtained. By setting the thickness to 10 μm or less, it can be used as a raw material for magnetic powder such as a soft magnetic powder magnetic core. Further, since the average particle size of the iron nitride particles is 100 nm or less, a magnet material having a higher coercive force can be obtained. From these facts, the average particle size of the iron nitride particles is more preferably 10 nm or more and 10 μm or less, and further preferably 10 nm or more and 100 nm or less.

The average particle size of the iron nitride particles shall be measured as follows. The particle size distribution is analyzed by analysis software equipped with a particle (colony) counter for the image taken by observing the iron nitride particles with an electron microscope, and the average particle size is obtained based on the number of particles. The number of particles to be analyzed shall be at least 20 as required for statistics.
As the electron microscope, JSM7000F or the like manufactured by JEOL can be used in the case of a scanning electron microscope, and JEM-2100 (EDX, CMOS replacement) or the like can be used in the case of a transmission electron microscope. Further, in order to calculate the average particle size from the image of the iron nitride particles observed with an electron microscope, for example, the average particle size (ferret diameter) may be calculated using ImageJ or the like as analysis software.

(Anti-corrosion layer)
The iron nitride particles according to the embodiment of the present invention preferably have an anticorrosion layer on the surface in order to suppress deterioration due to an atmosphere such as the atmosphere. As the anticorrosion layer, for example, iron nitride having a composition different from that of α''-Fe ₁₆ N ₂ can be considered. For example, ε-Fe _2-3 N having high corrosion resistance can be used. Since iron nitride as an anticorrosion layer has a phase different from that of α''-Fe ₁₆ N ₂ in nitriding ratio, it can be produced by changing the nitriding treatment method. For example, the surface can be irradiated with nitrogen plasma to form an anticorrosion layer made of iron nitride.
As the other anticorrosion layer, iron carbide or iron oxide can be applied. In the case of iron oxide, it can be formed by subjecting a gentle oxidation treatment after the formation of iron nitride particles. Further, in addition to the iron system, even if SiO ₂ or Al ₂ O ₃ is provided on the surface of the iron nitride particles, the anticorrosion layer can be obtained.
The thickness of the anticorrosion layer is preferably 0.5 nm or more and 20 nm or less. When the thickness of the anticorrosion layer is 0.5 nm or more, deterioration of iron nitride particles due to an atmosphere such as the atmosphere can be suppressed. Further, when the thickness of the anticorrosion layer is 20 nm or less, it is possible to suppress the influence of strain and the like on the nitride layer, and it is possible to generate the anticorrosion layer without much labor and time. The thickness of the anticorrosion layer is more preferably 1 nm or more and 10 nm or less.

<Manufacturing method of iron nitride particles>
The method for producing iron nitride particles according to the embodiment of the present invention is the above-mentioned method for producing iron nitride particles according to the embodiment of the present invention. As shown in FIG. 1, the method for producing iron nitride particles according to the embodiment of the present invention is an electrolysis step in which an anode 1 and a cathode 2 are provided in a molten salt 3 and each is connected to a power source 4 to perform molten salt electrolysis. It has. By using high-purity iron for the anode 1 and a nitrogen gas reducing electrode for the cathode 2, iron is dissolved in the molten salt 3 at the anode 1 and nitrogen gas is reduced at the cathode 2 in the molten salt 3. Nitride ion (N ^3- ) can be dissolved in. Then, iron nitride particles 5 containing α ″ -Fe ₁₆ N ₂ with high purity are precipitated in the molten salt 3. The power source 4 may be any one capable of controlling the electric potential, and for example, potentiometer galvanostat can be preferably used.
Further, the method for producing iron nitride particles according to the embodiment of the present invention may include, if necessary, a preparatory step for dissolving nitride ions in the molten salt 3 before the electrolysis step. Further, after the electrolysis step, there may be an anticorrosion layer forming step of forming an anticorrosion layer on the surface of the iron nitride particles 5. Each configuration will be described in detail below.

(Electrolysis process)
As described above, the electrolysis step is a step of providing a cathode and an anode in the molten salt to perform molten salt electrolysis.
− Anode −
Iron having a purity of 99% by mass or more is used for the anode. The iron used as the anode may intentionally or inevitably contain a component other than iron as long as it is 1% by mass or less. However, it is preferable that a component that is easier to nitride than iron and a component that affects the magnetic properties of α''-Fe ₁₆ N ₂ are contained as much as possible. For example, Ti, V, Cr, Mn, lanthanoids, and light metals such as Al and Si are more easily nitrided than iron, and thus inhibit the formation of α''-Fe ₁₆ N ₂ during electrolysis. The higher the purity of iron used for the anode, the more preferable.
The shape of iron used as the anode is not particularly limited, and may be appropriately selected depending on the purpose, such as a flat plate shape.

-Cathode-
A nitrogen gas reducing electrode (hereinafter, simply referred to as “gas electrode”) is used as the cathode. Nitride ions (N ^3- ) can also be generated in the molten salt by supplying nitrogen gas to the gas electrode and electrochemically reducing the nitrogen. As the gas electrode, any known electrode can be used as long as it can supply a gas containing nitrogen gas to the electrode surface, but it is preferable that the gas electrode has the structure shown in FIGS. 2 to 5. ..

The gas electrode shown in FIG. 2 is a gas electrode including a tubular electrode member 22 having an internal space that serves as a flow path for a gas containing nitrogen gas. The lead wire 21 may be connected to the tubular electrode member 22 to be connected to the cathode side of the power supply, and the counter electrode may be connected to the anode side of the power supply to apply an electric potential. Then, by supplying a gas containing nitrogen gas to the internal space of the tubular electrode member 22, the nitrogen gas is reduced on the surface of the tubular electrode member 22 facing the internal space, and nitride ions (N) are contained in the molten salt. It can be dissolved as ^3- ).

Further, like the gas electrode shown in FIG. 3, it is preferable to dispose a conductive porous member 33 at the tip of the internal space of the tubular electrode member 32. The porous member 33 may have a large number of communication holes that communicate between one surface and the other surface. Since the porous member 33 has a communication hole, the gas supplied to the internal space of the gas electrode can be passed to the outside of the gas electrode. Further, the communication hole may be, for example, a hole that goes straight from one surface of the porous member 33 toward the other surface, or is a hole formed by a complicated structure such as a three-dimensional network structure. It may be. When a gas electrode having the porous member 33 at the tip of the internal space is arranged in the molten salt, the inside of the communication hole is filled with the molten salt. The lead wire 31 may be connected to the tubular electrode member 32 to be connected to the cathode side of the power supply, and the counter electrode may be connected to the anode side of the power supply to apply an electric potential. Since the porous member 33 is conductive, by supplying a gas containing nitrogen gas to the internal space of the gas electrode, the nitrogen gas is reduced on the surface of the porous member 33 communication hole. As a result, the nitride ion (N ^3- ) can be dissolved in the molten salt.

The tubular electrode members (22, 32) and the porous member 33 are preferably materials that are inert in the molten salt, and are platinum, gold, or alloys thereof, glassy carbon, graphite, stainless steel, nickel, or nickel-based. An alloy or the like can be preferably used. The tubular electrode member 32 and the porous member 33 may be made of the same material or different materials.

As shown in FIG. 4, the gas electrode may include an electrode member 43 and a tubular member 42. The tubular member 42 may have an internal space that serves as a flow path for a gas containing nitrogen gas, and the electrode member 43 may be arranged in the internal space of the tubular member 42. Then, the lead wire 41 may be connected to the electrode member 43 to be connected to the cathode side of the power supply, and the counter electrode may be connected to the anode side to apply the potential. At this time, by supplying a gas containing nitrogen gas to the internal space of the tubular member 42, the nitrogen gas is reduced on the surface of the electrode member 42 and dissolved as nitride ions (N ^3- ) in the molten salt. Can be done.

Further, as the electrode member 43, as shown in FIG. 5, it is preferable to use a porous body 53 having a skeleton having a three-dimensional network structure. As a result, the surface area of the electrode can be increased, and the efficiency of dissolving the nitrogen gas supplied to the space inside the tubular member 52 in the molten salt can be further increased.

The tubular members (42, 52) do not have to be conductive, and may be made of a material that is stable in the molten salt. On the other hand, it is desirable that the electrode member 43 and the porous body 53 are conductive materials and are inert materials in the molten salt. As the electrode member 43, for example, platinum, gold, or an alloy thereof, glassy carbon, graphite, stainless steel, nickel, a nickel-based alloy, or the like can be preferably used. Further, as the porous body 53, for example, a nickel porous body having a skeleton having a three-dimensional network structure can be mentioned.
The higher the efficiency of the gas electrode, the more the portion forming the three-phase interface of the nitrogen gas, the molten salt, and the current-carrying portion of the gas electrode. Therefore, the gas electrode of the embodiment shown in FIGS. 3 and 5 in which a porous member is used for the energized portion is more effective.

As described above, the gas electrode is supplied with a gas containing nitrogen gas. As a result, the nitrogen gas is reduced on the surface of the electrode and dissolved in the molten salt as nitride ions.
As the gas supplied to the gas electrode, in addition to nitrogen gas, a mixed gas of a gas that does not affect the molten salt and nitrogen gas can also be used. As the gas to be mixed with the nitrogen gas, for example, argon (Ar) gas can be preferably used. When supplying a mixed gas of nitrogen gas and another gas, it is preferable that the gas has a high concentration of nitrogen gas in consideration of the reaction efficiency on the electrode surface. That is, it is desirable to adjust the concentration so that the maximum amount of nitrogen gas that can be reacted by the electrode used is supplied.

From the viewpoint of increasing the efficiency of nitride ion generation, the flow rate of the gas containing nitrogen gas is preferably set to a flow rate capable of supplying the maximum amount of nitrogen gas that can be reacted at the electrode.
Further, the unreacted gas discharged from the gas electrode may be recovered and circulated so as to be supplied to the gas electrode again.

− Molten salt −
As the molten salt, one that melts at 250 ° C. or lower to become a liquid may be selected. As the molten salt having a low melting point and being relatively easily available, for example, a halide of an alkali metal, a halide of an alkaline earth metal, or a mixture thereof is preferable. In general, a multi-component salt has a lower melting point than a single-component salt, so it is preferable to use a mixture of a plurality of types of salts. The alkali metal halide is preferably bromide, iodide or a mixture of bromide and iodide. Similarly, the halide of the alkaline earth metal is preferably bromide, iodide or a mixture of bromide and iodide. Salts of iodide and bromide are preferable because they can be melted at a low temperature and are easy to handle.

The alkali metal is preferably one or more selected from the group consisting of Li, K and Cs. Further, the alkaline earth metal is preferably one or more selected from the group consisting of Mg, Ca, Sr and Ba. Halides of these alkali metals and alkaline earth metals can be melted at a low melting point and are relatively easily available.

From the above viewpoint, the molten salt is preferably, for example, LiBr-CsBr, LiBr-KBr-CsBr, Li-KI, Li-CsI, Li-KI-CsI and the like.
When the molten salt contains Li ⁺ , K ⁺ and Cs ⁺ , the Li ⁺ content is 40 mol% or more and 80 mol% or less, and the K ⁺ content is 5 mol% or more, 30 mol% or less, Cs ^+. The content of is preferably 10 mol% or more and 40 mol% or less. As a result, a molten salt having a low melting point can be obtained.
The content of Li ^{+ in} the molten salt is more preferably 45 mol% or more and 75 mol% or less, and further preferably 50 mol% or more and 70 mol% or less.
The content of K ^{+ in} the molten salt is more preferably 7 mol% or more and 25 mol% or less, and further preferably 9 mol% or more and 20 mol% or less.
The content of Cs ^{+ in} the molten salt is more preferably 15 mol% or more and 35 mol% or less, and further preferably 20 mol% or more and 30 mol% or less.

-Electrolysis conditions-
The potential applied to the anode during molten salt electrolysis is preferably about 0.5 V or more and 3.5 V or less based on Li ⁺ / Li. When iron ions are dissolved in the molten salt, iron nitride containing α''-Fe ₁₆ N ₂ can be obtained by setting the potential applied to the anode to 0.5 V (vs. Li ⁺ / Li) or higher. Particles can be generated. When iron ions are not dissolved in the molten salt, the potential applied to the anode is set to more than 1.5 V (vs. Li ⁺ / Li) to dissolve the iron used as the anode and α. ''-Iron nitride particles containing -Fe ₁₆ N ₂ can be generated. On the other hand, by setting the potential applied to the anode to 3.5 V (vs. Li ⁺ / Li) or less, iron can be dissolved in the anode without oxidizing anions in the molten salt, for example, halide ions. it can.
The time for performing the molten salt electrolysis is not particularly limited, and it may be the time during which the target α''-Fe ₁₆ N ₂ is sufficiently formed.

The source of iron ions for synthesizing iron nitride particles is not limited to the above-mentioned anodic dissolution of iron. For example, a predetermined amount of iron halide may be added to the molten salt to supply iron ions. As the iron halide, for example, FeCl ₃ , FeBr ₃ , FeCl ₂ , FeBr ₂ , FeI _{2 and the} like can be preferably used. The amount of the iron halide added is preferably such that the concentration of the iron halide in the molten salt is 0.01 mol% or more and 5 mol% or less. By setting the concentration of the iron halide to 0.01 mol% or more, iron nitride particles containing α''-Fe ₁₆ N ₂ can be generated even when the iron used for the anode is not dissolved in the electrolysis step. Can be done. Further, by setting the concentration of the iron halide to 5 mol% or less, it is possible to suppress the rapid consumption of nitride ions and generate iron nitride particles containing α''-Fe ₁₆ N ₂ . From these viewpoints, when an iron halide is added to the molten salt, it is more preferable that the concentration of the iron halide in the molten salt is 0.1 mol% or more and 2 mol% or less. It is more preferable that the content is 0.2 mol% or more and 1 mol% or less.

Further, by performing a heat treatment on the iron nitride particles after the molten salt electrolysis, the formation of α''-Fe ₁₆ N ₂ may be promoted. In this case, the formation of α ″ -Fe ₁₆ N ₂ may be further promoted by quenching by rapidly cooling from the heat treatment temperature after the heat treatment.
The heat treatment of the iron nitride particles is preferably performed at room temperature or higher and lower than the molten salt electrolysis treatment temperature, for example, at 15 ° C. or higher and 200 ° C. or lower. The atmosphere in which the heat treatment is performed is not particularly limited, and the heat treatment may be performed in an electrolytic solution or in a gas atmosphere.

Iron nitride particles having an α''-Fe ₁₆ N ₂ content of 30% by mass or more precipitated in the molten salt can be recovered by filtration or the like. After that, it can be used as a raw material for magnetic members by washing with water and drying. As a result, iron nitride particles containing α''-Fe ₁₆ N ₂ at a high concentration and having high dispersibility can be obtained at low cost.

(Preparation process)
The preparatory step is a step performed before the electrolysis step, and is a step of dissolving the nitride ion (N ^3- ) in the molten salt.
For example, it is possible to produce a nitride ion in the molten salt by dissolving with the addition of Li 3 _N in the molten salt. The amount of nitride ion, e.g., Li ₃ concentration of N is 0.05 mol% or more, a Li ₃ N can be added to the molten salt to be equal to or less than 5 mol%. By setting the concentration of Li ₃ N to 0.05 mol% or more, a sufficient amount of nitride ions for electrodepositing α''-Fe ₁₆ N ₂ in the electrolysis step performed following the preparatory step can be obtained. It can be produced in molten salt. Further, since the concentration of Li 3 _N is less 5 mol%, it is possible to suppress an increase in melting point of the molten salt. From these viewpoints, the addition amount of the Li ₃ N is, Li ₃ N concentrations 0.1 mol% or more, more preferably to be not more than 3 mol%, 0.2 mol% or more, so as to be less 2 mol% Is more preferable.
When α''-Fe ₁₆ N ₂ begins to electrodeposit in the electrolysis step, the nitride ions in the molten salt are consumed, but the nitrogen gas sent to the cathode is reduced to become nitride ions in the molten salt. Is supplied to.

(Anti-corrosion layer forming process)
The anticorrosion layer forming step is a step performed after the electrolysis step, and is a step of forming an anticorrosion layer on the surface of the iron nitride particles formed by the electrolysis step. The anticorrosion layer formed on the surface of the iron nitride particles is preferably ε-Fe _2-3 N, iron carbide or iron oxide.
When iron nitride having a phase different from that of α''-Fe ₁₆ N ₂ such as ε-Fe _2-3 N is formed as the anticorrosion layer, for example, it is formed by changing the nitriding method. Can be done. That is, after the electrolytic step, the surface of the iron nitride particles is nitrided by irradiating with nitrogen plasma to form an anticorrosion layer made of iron nitride containing ε-Fe _2-3 N, which has excellent corrosion resistance, on the surface of the iron nitride particles. Can be done.
When iron carbide is formed as an anticorrosion layer, for example, after cleaning, a hydrocarbon material (liquid hydrocarbon, etc.) may be applied and baked in an inert atmosphere furnace, or heat treatment may be performed in a CO atmosphere. Good.
When iron oxide is formed as the anticorrosion layer, iron nitride particles containing α''-Fe ₁₆ N ₂ may be oxidized under mild conditions. As a condition of the gentle oxidation treatment, for example, Fe ₃ O ₄ may be formed by heat treatment at about 100 ° C. after washing.
In addition, SiO ₂ or Al ₂ O ₃ may be formed as the anticorrosion layer.

Hereinafter, the present invention will be described in more detail based on Examples, but these Examples are examples, and the iron nitride particles of the present invention and the method for producing the same are not limited thereto. The scope of the present invention is indicated by the scope of claims, and includes all modifications within the meaning and scope equivalent to the scope of claims.

[Example 1]
LiBr, KBr and CsBr were mixed so that the mixing ratio was 56.1: 18.9: 25.0 in terms of molar ratio and heated to 250 ° C. to prepare a molten salt.
A 5 mm × 5 mm × 1 mmt Fe plate was placed as an anode, and a nitrogen gas reducing electrode was placed in the molten salt as a cathode. Further, an Al—Li alloy was used as a reference electrode. The temperature of the molten salt was 240 ° C.
The nitrogen gas reduction electrode has the configuration shown in FIG. Specifically, a glassy carbon pipe (outer diameter 13 mm, inner diameter 9 mm) was used as a tubular electrode member, and nitrogen gas was supplied into the pipe. Nitrogen gas was constructed so that it was ejected into the molten salt from the tip of the pipe. The flow rate of nitrogen gas was 20 ml / min.
The anode and cathode are connected to a potentiometer / galvanostat as a power source whose potential can be controlled, a potential of 2.0 V is applied to the anode on a Li ⁺ / Li basis, and molten salt electrolysis is performed at a constant potential for 3 hours to nitride. Iron particle No. 1 was manufactured. Molten salt electrolysis was performed in a glove box with an Ar flow atmosphere.

[Example 2]
The iron nitride particle No. 1 was obtained in the same manner as in Example 1 except that the temperature of the molten salt was set to 245 ° C. in Example 1. 2 was manufactured.

[Comparison example]
The iron nitride particle No. 1 was obtained in the same manner as in Example 1 except that the temperature of the molten salt was set to 255 ° C. in Example 1. 3 was manufactured.

表１の結果より、溶融塩電解時に溶融塩の温度を２５０℃以下とすることでα’’−Ｆｅ_１６Ｎ_２を含有する窒化鉄粒子が得られるが、２５０℃を超えると得られないことがわかる。 -Evaluation-
(Generation phase)
The formation of powder in the molten salt was observed under all the conditions of Examples 1, 2 and Comparative Example.
The production phase of the obtained powder was analyzed by an X-ray diffractometer. The results are shown in Table 1.

From the results in Table 1, iron nitride particles containing α''-Fe ₁₆ N ₂ can be obtained by setting the temperature of the molten salt to 250 ° C or lower during molten salt electrolysis, but it cannot be obtained when the temperature exceeds 250 ° C. I understand.

(Average particle size)
The iron nitride particle No. obtained as described above. 1-No. The average particle size of No. 3 was observed with an electron microscope (JSM 7000F manufactured by JEOL Ltd.), analyzed with ImageJ (analysis software), and the average particle size (ferret diameter) was measured.
As a result, the iron nitride particle No. The average particle size of No. 1 is 40 nm, and the iron nitride particles No. 2 is 43 nm, and the iron nitride particle No. 3 was 55 nm.

(Content rate of α''-Fe ₁₆ N ₂ )
The iron nitride particle No. obtained as described above. 1, No. The content of α''-Fe ₁₆ N _{2 in 2} was measured by an X-ray diffractometer.
As a result, the iron nitride particle No. The content of α''-Fe ₁₆ N ₂ in 1 was 54% by mass, and the iron nitride particle No. 2 was 33% by mass.

1 Anode 2 Cathode 3 Molten salt 4 Power supply 5 Iron nitride particles 21 Lead wire 22 Cylindrical electrode member 31 Lead wire 32 Cylindrical electrode member 33 Porous member 41 Lead wire 42 Cylindrical member 43 Electrode member 51 Lead wire 52 Cylindrical member 53 Porous

Claims (10)

The average particle size is 10 nm or more and 10 μm or less, the content of α''-Fe ₁₆ N ₂ is 30% by mass or more, the iron nitride particles have an anticorrosion layer on the surface, and the anticorrosion layer is ε-Fe. A method for producing iron nitride particles that are _2-3 N or iron carbide .
By providing iron having a purity of 99% by mass or more as an anode and a nitrogen gas reducing electrode as a cathode in the molten salt and performing molten salt electrolysis, the content of α''-Fe ₁₆ N _{2 in} the molten salt Has an electrolysis step of precipitating iron nitride particles in an amount of 30% by mass or more.
In the electrolysis step, the temperature of the molten salt is 250 ° C. or lower.
After the electrolysis step, there is an anticorrosion layer forming step of forming an anticorrosion layer on the surface of the iron nitride particles.
The anticorrosion layer is ε-Fe _2-3N or iron carbide.
A method for producing iron nitride particles. The method for producing iron nitride particles according to claim 1 , wherein in the electrolysis step, the potential applied to the anode is 0.5 V or more and 3.5 V or less based on Li ⁺ / Li. The method for producing iron nitride particles according to claim 1 or 2 , further comprising a preparatory step for generating nitride ions (N ^3- ) in the molten salt before the electrolysis step. The molten salts are alkali metal halides, halides, or mixtures of these alkaline earth metals, the manufacturing method of the iron nitride particles according to any one of claims 1 to 3. The method for producing iron nitride particles according to claim 4 , wherein the alkali metal halide is an alkali metal bromide, iodide, or a mixture of bromide and iodide. The method for producing iron nitride particles according to claim 4 or 5 , wherein the halide of the alkaline earth metal is a bromide of the alkaline earth metal, iodide, or a mixture of bromide and iodide. The method for producing iron nitride particles according to any one of claims 4 to 6 , wherein the alkali metal is at least one selected from the group consisting of Li, K and Cs. The method for producing iron nitride particles according to any one of claims 4 to 7 , wherein the alkaline earth metal is at least one selected from the group consisting of Mg, Ca, Sr and Ba. The molten salt is LiBr-KBr-CsBr or LiI-KI-CsI, a manufacturing method of the iron nitride particles as claimed in any one of claims 8. The molten salt contains Li ⁺ , K ⁺ and Cs ⁺ , and has a Li ⁺ content of 40 mol% or more and 80 mol% or less, a K ⁺ content of 5 mol% or more and 30 mol% or less, and a Cs ⁺ content. 10 mol% or more and less 40 mol%, the production method of the iron nitride particles according to any one of claims 1 to 9.

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