TW201701524A - Negative electrode and active material for nonaqueous electrolyte secondary battery, nonaqueous electrolyte secondary battery, and method for manufacturing negative electrode material for nonaqueous electrolyte secondary battery - Google Patents

Abstract

To provide a negative electrode active material for a nonaqueous electrolyte secondary battery, which enables the increase in battery capacity and the enhancement in cycle characteristic and battery initial efficiency. A negative electrode active material for a nonaqueous electrolyte secondary battery comprises: negative electrode active material particles including a silicon compound (SiO: 0.5 ≤ x ≤ 1.6). The negative electrode active material particles each have a carbon coating on at least part of its surface. The carbon coating is 5-1000 m2/g in specific surface area according to a multi-point BET method in which the carbon coating is isolated from the negative electrode active material particle for measurement. The carbon coating is 1.0 x 10<SP>-3</SP> to 1.0 [Omega]cm in compression resistivity when being subjected to compression to a density of 1.0 g/cm3, in which the carbon coating was isolated from the negative electrode active material particle for measurement.

Description

Negative electrode active material for nonaqueous electrolyte secondary battery, negative electrode for nonaqueous electrolyte secondary battery, nonaqueous electrolyte secondary battery, and method for producing negative electrode material for nonaqueous electrolyte secondary battery

The present invention relates to a negative electrode active material for a nonaqueous electrolyte secondary battery, a negative electrode for a nonaqueous electrolyte secondary battery, a nonaqueous electrolyte secondary battery, and a method for producing a negative electrode material for a nonaqueous electrolyte secondary battery.

In recent years, small electronic devices such as mobile terminals have been widely used, and further miniaturization, weight reduction, and long life have been strongly demanded. With such market demands, especially small and lightweight, developments in secondary batteries with high energy density are progressing. This secondary battery is also reviewed not only for small electronic devices, but also for the application of large-scale electronic devices such as automobiles and electric power storage systems represented by houses.

Among them, the lithium ion secondary battery is easy to be small and high in capacity, and is expected to have a higher energy density than a lead battery or a nickel cadmium battery.

The lithium ion secondary battery includes a positive electrode and a negative electrode, a separator, and an electrolyte. This negative electrode contains a negative electrode active material related to a charge and discharge reaction.

As the negative electrode active material, a carbon material is widely used, and on the other hand, based on recent market requirements, further improvement in battery capacity is required. As an element for improving the battery capacity, ruthenium was used as a material for the negative electrode active material. This is because the theoretical capacity of ruthenium (4199 mAh/g) is more than 10 times larger than the theoretical capacity of graphite (372 mAh/g), and a large increase in battery capacity can be expected. The development of the ruthenium material as the material of the negative electrode active material is not only for ruthenium, but also for compounds represented by alloys and oxides. The shape of the active material was examined from the standard coating form of the carbon material to the integrated type directly deposited on the current collector.

However, when a negative electrode active material containing ruthenium as a main raw material is used, the ruthenium-based active material particles expand and contract during charge and discharge, and are likely to be broken mainly in the vicinity of the surface layer of the lanthanum-based active material particles. Further, an ionic substance is formed inside the active material, and the lanthanide-based active material particles are easily broken. Since the surface of the negative electrode active material is broken to form a new surface, the reaction area of the active material increases. At this time, the decomposition reaction of the electrolytic solution occurs on the new surface, and the electrolytic solution is consumed by forming the film of the decomposition product of the electrolytic solution on the new surface, so that the cycle characteristics are liable to lower.

In order to improve the initial efficiency of the battery or the cycle characteristics, various types of negative electrode materials and electrode compositions for lithium ion secondary batteries using a ruthenium material as a main material have been reviewed.

Specifically, for the purpose of obtaining good cycle characteristics or high safety, a gas phase method is used to simultaneously deposit tantalum and amorphous germanium dioxide (for example) For example, refer to Patent Document 1). Moreover, in order to obtain high battery capacity or safety, a carbon material (electron conductive material) is provided on the surface layer of the cerium oxide particles (see, for example, Patent Document 2). In addition, in order to improve the cycle characteristics, high input/output characteristics are obtained, and an active material containing cerium and oxygen is formed, and an active material layer having a high oxygen ratio in the vicinity of the current collector is formed (for example, see Patent Document 3). In addition, in order to improve the cycle characteristics, oxygen is contained in the ruthenium-based active material, and the average oxygen content is 40 at% or less, and the oxygen content is increased in a place close to the current collector (see, for example, Patent Document 4).

Further, in order to improve the initial charge and discharge efficiency, a nanocomposite containing a Si phase, SiO ₂ or M _y O metal oxide is used (for example, see Patent Document 5). In addition, in order to improve the initial charge and discharge efficiency, a Li-containing material is added to the negative electrode, Li is decomposed at a high potential of the negative electrode, and pre-doping is performed to return Li to the positive electrode (see, for example, Patent Document 6).

Further, in order to improve the cycle characteristics, SiO _x (0.8 ≦ x ≦ 1.5, particle size range = 1 μm to 50 μm) and a carbon material are mixed and fired at a high temperature (see, for example, Patent Document 7). Further, in order to improve the cycle characteristics, the molar ratio of oxygen to lanthanum in the negative electrode active material is 0.1 to 1.2, and the maximum and minimum molar ratios of oxygen to yttrium near the interface between the active material and the current collector are obtained. The difference is 0.4 or less, and the active material is controlled (for example, refer to Patent Document 8). Further, in order to improve the battery load characteristics, a metal oxide containing lithium is used (for example, see Patent Document 9). Further, in order to improve the cycle characteristics, a water-repellent layer such as a decane compound is formed on the surface layer of the ruthenium material (see, for example, Patent Document 10).

In addition, in order to improve the cycle characteristics, a ruthenium oxide is used, and a graphite film is formed on the surface layer to impart conductivity (for example, see Patent Document 11). In this case, in Patent Document 11, on the shift value obtained from the Raman spectra associated with the graphite film, in 1330cm ^-1 and 1580cm ^-1 broad peak appeared, their intensity ratio I ₁₃₃₀ / I ₁₅₈₀ be 1.5 <I ₁₃₃₀ /I ₁₅₈₀ <3.

Further, in order to improve the battery capacity and the cycle characteristics, particles having a ruthenium microcrystal phase dispersed in ruthenium dioxide are used (for example, see Patent Document 12). In addition, in order to improve the overcharge and overdischarge characteristics, a ruthenium oxide whose atomic ratio of yttrium and oxygen is controlled to 1:y (0 < y < 2) is used (for example, see Patent Document 13).

[Previous Technical Literature] [Patent Literature]

[Patent Document 1] Japanese Patent Laid-Open Publication No. 2001-185127

[Patent Document 2] Japanese Patent Laid-Open Publication No. 2002-042806

[Patent Document 3] Japanese Laid-Open Patent Publication No. 2006-164954

[Patent Document 4] Japanese Patent Laid-Open Publication No. 2006-114454

[Patent Document 5] Japanese Patent Laid-Open Publication No. 2009-070825

[Patent Document 6] Japanese Patent Publication No. 2013-513206

[Patent Document 7] Japanese Laid-Open Patent Publication No. 2008-282819

[Patent Document 8] Japanese Patent Laid-Open Publication No. 2008-251369

[Patent Document 9] Japanese Patent Laid-Open Publication No. 2008-177346

[Patent Document 10] Japanese Patent Laid-Open Publication No. 2007-234255

[Patent Document 11] Japanese Patent Laid-Open Publication No. 2009-212074

[Patent Document 12] Japanese Patent Laid-Open Publication No. 2009-205950

[Patent Document 13] Japanese Invention Patent No. 2997741

As described above, in recent years, small electronic devices such as mobile terminals have been used for high performance and multi-function, and non-aqueous electrolyte secondary batteries of main power sources, particularly lithium ion secondary batteries, have been required to have an increase in battery capacity. As one method for solving this problem, development of a nonaqueous electrolyte secondary battery composed of a negative electrode using a tantalum material as a main material is desired. In addition, a nonaqueous electrolyte secondary battery using a tantalum material is desired to have a cycle characteristic similar to that of a nonaqueous electrolyte secondary battery using a carbon material.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a negative electrode active material for a nonaqueous electrolyte secondary battery which can increase battery capacity and improve cycle characteristics and initial battery efficiency. Moreover, the present invention also aims to provide a nonaqueous electrolyte secondary battery using the negative electrode active material. In addition, the present invention also provides a method for producing a negative electrode material for a nonaqueous electrolyte secondary battery which is excellent in battery capacity, cycle characteristics, and initial battery efficiency.

In order to achieve the above object, the present invention provides a negative electrode active material for a nonaqueous electrolyte secondary battery, which comprises a negative electrode active material particle and the negative electrode active material particle contains a nonaqueous electrolyte of a cerium compound (SiO _x : 0.5 ≦ x ≦ 1.6). In the negative electrode active material for a secondary battery, the negative electrode active material particle has a carbon film formed on at least a part of the surface, and the carbon film is separated from the negative electrode active material particle by the carbon film, and the measured multi-point BET method is used. The specific surface area is 5 m ² /g or more and 1000 m ² /g or less, and the carbon film is separated from the negative electrode active material particles by the carbon film, and the measured compressive resistivity is reduced to a density of 1.0 g/cm ³ . It is 1.0 × 10 ^-3 Ω ‧ cm or more and 1.0 Ω ‧ cm or less.

The negative electrode active material of the present invention has a negative electrode active material particle containing a ruthenium compound, and the battery capacity is particularly larger than the case where the carbon-based active material particle is used as a host, and at least a part of the surface of the negative electrode active material particle containing the ruthenium compound is passed through the carbon film. It is coated to have excellent electrical conductivity. In addition, when the specific surface area of the carbon film which is separated from the negative electrode active material particles is in the above range, the impregnation property of the electrolyte solution of the battery becomes good. When the specific surface area of the carbon film to be separated is within the above range, the amount of the binder adsorbed on the surface of the negative electrode active material particle is appropriate, and the adhesiveness is improved. In addition, when the compression resistivity of the carbon film to be separated is as described above, the conductivity of the surface of the negative electrode active material particle is sufficient, and minute precipitation of Li due to power concentration on the surface is less likely to occur. Further, by measuring the specific surface area and the compressive resistivity of the separated carbon film, the influence of the ruthenium compound or the like can be removed, and the characteristics of the pure carbon film can be measured. Such a negative electrode active material has a high capacity as a negative electrode, and exhibits an excellent capacity retention ratio and primary efficiency. Hereinafter, the negative electrode activity of the ruthenium compound coated with the carbon film in the present invention is also used. The substance particles are called "lanthanide active material particles".

In this case, the true density of the carbon film is preferably in the range of 1.2 g/cm ³ or more and 1.9 g/cm ³ or less.

When the true density of the carbon film is 1.9 g/cm ³ or less, the carbon film on the surface of the ruthenium compound is not excessively dense, and the electrolyte solution is easily impregnated into the ruthenium compound inside, and has cycle characteristics, initial charge and discharge characteristics, and the like. Battery characteristics are further improved. In addition, when the true density is 1.2 g/cm ³ or more, the specific surface area of the negative electrode active material particles containing the ruthenium compound is an appropriate value, and when the negative electrode is produced, only the appropriate amount of the binder is adsorbed to improve the effect of the binder, and the battery is improved. The characteristics are further improved.

In this case, the carbon film is separated from the carbon film by the negative electrode active material particle, and the separated carbon film is added to the measurement container so that the mass per unit area is 0.15 g/cm ² . when the compressed density is preferably 50MPa pressure compressed 1.0g / cm ³ than 1.8g / cm ³ or less.

In the negative electrode active material in which the carbon-based film which is separated from the ruthenium-based active material particles satisfies the above-mentioned compression density, the conductive auxiliary agent is easily entangled in the lanthanum-based active material particles when the negative electrode is formed, whereby the conductivity inside the electrode can be excellent.

In this case, the content of the carbon film is preferably 0.1% by mass or more and 25% by mass or less based on the negative electrode active material particles.

When the carbon film is provided in such a ratio, the negative electrode active material particles containing a high-capacity ruthenium compound can be contained in an appropriate ratio, and a sufficient battery capacity can be secured.

Further, in this case, it is preferable that the carbon film is formed by separating the carbon film from the negative electrode active material particles, and the nitrogen gas is removed from the Isopac classification type in the adsorption and desorption isotherm of the nitrogen gas. Or the characteristics of type III.

Since the adsorption-desorption isotherm measured by the carbon film which is separated from the ruthenium-based active material particles is a type II or a type III, it can be said that the surface of the carbon film is non-porous, so that when the negative electrode is produced, adhesion can be performed. The consumption of the agent is suppressed to a minimum, and since the binder is not excessively adsorbed, an excellent effect is achieved in the adhesion of the ruthenium-based active material particles containing a ruthenium compound having a large amount of expansion and contraction.

In this case, by reacting the negative electrode active material particles with a solution containing hydrofluoric acid and nitric acid, the ruthenium compound is removed from the negative electrode active material particles, whereby the carbon film can be separated.

The individual separation of the carbon film can be specifically carried out by such a method.

Also at this time, the carbon-based coating film is preferably in the Raman spectrum obtained by Raman spectroscopic analysis at 1330cm ^-1 and 1580cm ^-1 peak scattering, scattering peak intensity ratio of their I ₁₃₃₀ / I ₁₅₈₀ satisfies 0.7 < I ₁₃₃₀ /I ₁₅₈₀ <2.0.

The carbon film of the lanthanum-based active material particles can optimize the ratio of the carbon material having a diamond structure and the carbon material having a graphite structure contained in the carbon film as long as the peak intensity ratio is satisfied.

In this case, the carbon film is preferably a fragment of the _Cy H _z- based compound detected by TOF-SIMS (time-of-flight secondary ion mass spectrometry) as a fragment of the _Cy H _z -based compound, and is detected at least in part. The range that satisfies 6≧y≧2, 2y+2≧z≧2y-2 is satisfied.

As long as the surface state of the compound fragment such as the _Cy H _z- based fragment is detected by TOF-SIMS, the compatibility with the negative electrode binder such as CMC (carboxymethyl cellulose) or polyimine is improved. The battery characteristics are further improved.

Further, at this time, in the fragment of the _Cy H _z -based compound detected by the carbon film, it is preferred that the detection intensity D of the C ₄ H ₉ in the TOF-SIMS and the detection intensity E of the C ₃ H ₅ satisfy 2.5 ≧ D / E≧0.3 relationship.

When the ratio of the detection intensity of C ₄ H ₉ and C ₃ H ₅ is within the above range, the effect of improving the conductivity by the carbon film can be made more effective.

In this case, the average thickness of the carbon film is preferably 5 nm or more and 5000 nm or less.

As long as the carbon film satisfies such an average thickness, sufficient conductivity can be imparted and the ratio of the cerium compound can be increased.

Further, at this time, the average coverage of the carbon film is preferably 30% or more.

When the negative electrode active material containing the lanthanum-based active material particles is used as the negative electrode active material of the lithium ion secondary battery, the carbon component is particularly effective in improving the conductivity.

In this case, the carbon film is preferably obtained by thermally decomposing a carbon-containing compound.

The carbon film obtained by such a method has a high average coverage on the surface of the lanthanum-based active material particles.

Further, at this time, in the above ruthenium compound, as the chemical shift value obtained from the ²⁹ Si-MAS-NMR spectrum, the peak area A of the amorphous ruthenium region given at -20 to -74 ppm is at -75 to -94 ppm. The peak area B of the crystalline bismuth region and the lithium niobate region and the peak area C of the vermiculite region given at -95 to -150 ppm are preferably satisfied to satisfy the formula (1); formula (1): 5.0 ≧ A/ B≧0.01, 6.0≧(A+B)/C≧0.02.

The ruthenium compound contained in the ruthenium-based active material particles is an amorphous ruthenium which suppresses expansion accompanying insertion of Li as long as it has a peak area ratio satisfying the above formula (1) in the ²⁹ Si-MAS-NMR spectrum. The ratio is high, and the expansion of the negative electrode is suppressed to obtain better cycle characteristics. Moreover, as long as it is such a case, since the ratio of the vermiculite component to the bismuth component and the lithium niobate component is small, the decrease in the electron conductivity in the ruthenium compound can be suppressed.

In this case, it is preferable that the negative electrode active material particle has a half value width (2θ) of a diffraction peak due to the Si (111) crystal plane obtained by X-ray diffraction, and is 1.2 or more, and is caused by the crystal face. The crystal size is 7.5 nm or less.

The ruthenium compound having such a half-value width and a crystallite size can improve battery characteristics because of low crystallinity and a small amount of Si crystal. Moreover, the formation of a stable Li compound can be carried out by the presence of such a low crystallinity compound.

Further, in this case, the median diameter of the negative electrode active material particles is preferably 0.5 μm or more and 20 μm or less.

As long as it is a negative electrode active material containing the quinone-based active material particles having such a median diameter, the storage and release of lithium ions during charging and discharging become easy, and the lanthanide-based active material particles are less likely to be broken. As a result, the capacity retention rate can be improved.

In this case, it is preferable that at least a part of the negative electrode active material particles contain Li.

In the lanthanide-based active material particles contained in the negative electrode, the initial efficiency is improved by containing the Li compound. In addition, as the initial efficiency of the negative electrode in the nonaqueous electrolyte secondary battery increases, the balance between the positive electrode and the negative electrode during the cycle test is suppressed, and the maintenance ratio is improved.

In addition, at least one part of the negative electrode active material particles of the present invention contains at least one of Li ₂ SiO ₃ and Li ₄ SiO ₄ in at least a part of the negative electrode active material particles.

As long as the lanthanum-based active material particles contain the above-mentioned lithium niobate which is relatively stable as the Li compound, the stability of the slurry at the time of electrode production is further improved.

Further, the negative electrode active material particle of the present invention is preferably a crystalline yttrium region and a citric acid which are obtained from a ²⁹ Si-MAS-NMR spectrum and have a chemical shift value of -75 to -94 ppm, which is obtained from the ²⁹ Si-MAS-NMR spectrum. The maximum peak intensity value H of the lithium region and the peak intensity value I of the vermiculite region given as a chemical shift value of -95 to -150 ppm satisfy the relationship of H>I.

In the lanthanum-based active material particles, if the amount of lithium niobate such as crystalline ruthenium or Li ₂ SiO ₃ is more than the SiO ₂ component, the insertion of Li can be sufficiently obtained. A negative electrode active material having an effect of improving battery characteristics.

Further, a test battery comprising a negative electrode comprising a mixture of a negative electrode active material for a nonaqueous electrolyte secondary battery and a carbon-based active material, and a counter electrode lithium was produced, and in the test battery, lithium was inserted into the non-aqueous battery. In the negative electrode active material for an electrolyte secondary battery, the charge current is charged and discharged from the negative electrode active material for the nonaqueous electrolyte secondary battery, and the charge and discharge are discharged 30 times, and a graph is drawn and displayed. The discharge capacity Q in each charge and discharge is determined by the relationship between the differential value dQ/dV of the potential V of the negative electrode based on the polar lithium and the potential V, after the Xth time (1≦X) In the discharge of ≦30), the potential V of the negative electrode preferably has a peak in the range of 0.40 V to 0.55 V.

The above-mentioned peak system in the V-dQ/dV curve is similar to the peak of the ruthenium material, and since the discharge curve on the high potential side is more sharply erected, it becomes easy to exhibit capacity when performing battery design. In addition, as long as the peaks are exhibited in charge and discharge within 30 times, the negative electrode active material forming a stable whole is formed.

Further, in this case, the negative electrode active material of the present invention preferably further contains carbon-based active material particles.

In the present invention, as long as the lanthanide-based active material particles further contain carbon-based active material particles, the capacity of the negative electrode can be increased. The amount is improved while the cycle characteristics and initial charge and discharge characteristics are obtained.

In this case, the mass ratio of the negative electrode active material particles is preferably 5% by mass or more based on the total mass of the negative electrode active material particles and the carbon-based active material particles.

The ratio of the negative electrode active material particles containing the ruthenium compound can further increase the battery capacity as long as it is as described above.

In this case, the average particle diameter F of the negative electrode active material particles is preferably in a relationship of 25 ≧G/F ≧ 0.5 with respect to the average particle diameter G of the carbon-based active material particles.

The average particle diameter G of the carbon-based active material particles and the average particle diameter F of the negative electrode active material particles containing the ruthenium compound satisfy the above relationship, thereby preventing breakage of the composite material layer. In addition, when the carbon-based active material particles are increased in the negative electrode active material particles containing the ruthenium compound, the bulk density and initial efficiency of the negative electrode during charging are improved, and the battery energy density is improved.

In this case, the carbon-based active material particles are preferably a graphite material.

The graphite material is preferably more excellent in primary efficiency and capacity retention than other carbon-based active materials.

In order to achieve the above object, the present invention provides a negative electrode for a nonaqueous electrolyte secondary battery, comprising: a negative electrode active material layer and a negative electrode current collector including the negative electrode active material for a nonaqueous electrolyte secondary battery; The active material layer is formed on the negative electrode current collector, and the negative electrode current collector contains carbon and sulfur, and the content thereof is 100 ppm by mass or less.

As described above, the negative electrode current collecting system constituting the negative electrode can contain carbon and sulfur in an amount as described above, thereby suppressing deformation of the negative electrode during charging.

In order to achieve the above object, the present invention provides a nonaqueous electrolyte secondary battery comprising the negative electrode active material for a nonaqueous electrolyte secondary battery.

As long as it is a nonaqueous electrolyte secondary battery using the negative electrode active material of the present invention, it has a high capacity and has excellent cycle characteristics and initial charge and discharge characteristics.

In order to achieve the above object, the present invention provides a method for producing a negative electrode material for a nonaqueous electrolyte secondary battery, which is a method for producing a negative electrode material for a nonaqueous electrolyte secondary battery comprising negative electrode active material particles, which is characterized by comprising: a step of preparing particles of a ruthenium compound represented by SiO _x (0.5 ≦ x ≦ 1.6); and a step of coating at least a part of a surface of the ruthenium compound particles with a carbon film; and selecting a ruthenium compound coated with the carbon film In the step of the particles, the carbon film is separated from the carbon film by the particles of the ruthenium compound coated with the carbon film, and the measured multi-point BET method has a specific surface area of 5 m ² /g or more and 1000 m ² /g or less. The particles coated with the ruthenium compound of the carbon film are separated from the carbon film, and the measured compressive resistivity is 1.0 × 10 ^-3 Ω ‧ cm or more and 1.0 Ω ‧ cm or less when compressed to a density of 1.0 g/cm ³ ; The particles of the selected ruthenium compound coated with the carbon film are used as the negative electrode active material particles to produce a negative electrode material for a nonaqueous electrolyte secondary battery.

As long as it is manufactured, it is made as described above By using the particles of the selected ruthenium compound coated with the carbon film as the negative electrode active material particles, it is possible to produce a negative electrode material for a nonaqueous electrolyte secondary battery which exhibits an excellent capacity retention rate and primary efficiency while exhibiting a high capacity.

When used as a negative electrode active material of a nonaqueous electrolyte secondary battery, the negative electrode active material of the present invention has a high capacity and can obtain excellent cycle characteristics and initial charge and discharge characteristics. Further, in the secondary battery including the negative electrode active material for a nonaqueous electrolyte secondary battery of the present invention, the same characteristics can be obtained. Moreover, the same effect can be obtained in an electronic device, a power tool, an electric car, an electric power storage system, or the like using the secondary battery of the present invention.

In addition, as long as it is a method for producing a negative electrode material of the present invention, a negative electrode material for a nonaqueous electrolyte secondary battery having high capacity and excellent cycle characteristics and initial charge and discharge characteristics can be produced.

10‧‧‧negative

11‧‧‧Negative current collector

12‧‧‧Negative active material layer

20‧‧‧Lithium secondary battery (laminate film type)

21‧‧‧Electrode body

22‧‧‧ positive lead (positive aluminum lead)

23‧‧‧Negative lead (negative nickel lead)

24‧‧‧Blinded film

25‧‧‧External components

Fig. 1 is a schematic cross-sectional view showing a negative electrode using a negative electrode active material for a nonaqueous electrolyte secondary battery of the present invention.

Fig. 2 is a graph for determining the density of a carbon coating film of the negative electrode active material particles in the present invention.

3 is an exploded view showing an example of a configuration of a nonaqueous electrolyte secondary battery (laminated thin film type lithium ion secondary battery) of the present invention.

[Formation of the Invention]

Hereinafter, embodiments of the present invention will be described, but the present invention is not limited thereto.

As described above, as a method of increasing the battery capacity of the nonaqueous electrolyte secondary battery, the negative electrode used as the main material of the ruthenium material is used as the negative electrode of the nonaqueous electrolyte secondary battery.

In the nonaqueous electrolyte secondary battery using the ruthenium material, it is desirable to have a cycle characteristic similar to that of the nonaqueous electrolyte secondary battery using a carbon material, but exhibits the same cycle stability as that of the nonaqueous electrolyte secondary battery using a carbon material. The negative electrode material has not been proposed. Further, in particular, the oxygen-containing cerium compound has a low initial efficiency compared with the carbon material, and is limited in terms of improvement in battery capacity.

Therefore, the inventors of the present invention have achieved the present invention by repeating the intensive efforts to obtain a negative electrode active material having good cycle characteristics and primary efficiency when used in a negative electrode of a nonaqueous electrolyte secondary battery.

The negative electrode active material for a nonaqueous electrolyte secondary battery of the present invention contains negative electrode active material particles. Further, the negative electrode active material particles are ruthenium-based active material particles containing a ruthenium compound (SiO _x : 0.5 ≦ x ≦ 1.6). Further, the lanthanum-based active material particles have a carbon coating on at least a part of the surface. In addition, the specific surface area of the multi-point BET method in which the carbon film is separated from the lanthanum-based active material particles is 5 m ² /g or more and 1000 m ² /g or less, and is measured by the separation of the lanthanum-based active material particles. The compression resistivity is 1.0 × 10 ^-3 Ω ‧ cm or more and 1.0 Ω ‧ cm or less when compressed to a density of 1.0 g/cm ³ .

Since the negative electrode active material of the present invention has lanthanum active material particles and has a large battery capacity, at least a part of the surface of the lanthanum active material particles is coated with a carbon film to have excellent conductivity.

In addition, when the specific surface area of the multi-point BET method measured from the ruthenium-based active material particles is less than 5 m ² /g, the impregnation property of the electrolytic solution is poor, and battery characteristics such as cycle characteristics and initial charge and discharge characteristics are deteriorated. In addition, when the specific surface area of the carbon coating film from which the lanthanum-based active material particles are separated is more than 1000 m ² /g, the coating property when the negative electrode active material is a slurry is deteriorated. In addition, when the compressive resistivity measured when the carbon film which is separated from the lanthanide-based active material particles is compressed to a density of 1.0 g/cm ³ exceeds 1.0 Ω ‧ cm, the conductivity of the surface of the lanthanum-based active material particles is insufficient. Battery characteristics such as cycle characteristics or initial charge and discharge characteristics are deteriorated. When the compression resistivity is less than 1.0 × 10 ^-3 Ω ‧ cm, current concentration tends to occur on the surface of the lanthanide-based active material particles, and minute precipitation of Li occurs during charge and discharge of the battery, and battery characteristics are deteriorated.

In contrast, the negative electrode active material of the present invention has a specific surface area of a multi-point BET method measured from a ruthenium-based active material particle by a carbon-separating film, and has a specific surface area of 5 m ² /g or more and 1000 m ² /g or less, and self-ceramic active material particles. The compressive resistivity measured by being separated from the carbon film is 1.0 × 10 ^-3 Ω ‧ cm or more and 1.0 Ω ‧ cm or less when compressed to a density of 1.0 g/cm ³ , so when used in a secondary battery, the above battery characteristics The variation is difficult to occur, and high battery capacity, good cycle characteristics, and initial charge and discharge characteristics can be obtained.

<1. Negative electrode for nonaqueous electrolyte secondary battery>

A negative electrode for a nonaqueous electrolyte secondary battery using the negative electrode material for a nonaqueous electrolyte secondary battery of the present invention will be described. Fig. 1 is a cross-sectional view showing a negative electrode for a nonaqueous electrolyte secondary battery (hereinafter also referred to simply as "negative electrode") according to an embodiment of the present invention.

[Composition of the negative electrode]

As shown in FIG. 1 , the negative electrode 10 has a configuration in which the negative electrode active material layer 12 is provided on the negative electrode current collector 11 . The negative electrode active material layer 12 can be provided on both sides of the negative electrode current collector 11 or only on one side. In addition, as long as the negative electrode active material of the present invention is used, the negative electrode current collector 11 may not be provided.

[Negative current collector]

The negative electrode current collector 11 is an excellent conductive material and is composed of a material having high mechanical strength. As a conductive material which can be used for the negative electrode collector 11, copper (Cu) or nickel (Ni) is mentioned, for example. The conductive material is preferably a material that does not form an intermetallic compound with lithium (Li).

The anode current collector 11 preferably contains carbon (C) or sulfur (S) in addition to the main element. This is to increase the physical strength of the anode current collector. In particular, when the active material layer which swells during charging is contained, the current collector has an effect of suppressing deformation of the electrode including the current collector as long as it contains the above-described elements. The above carbon and sulfur contents are not particularly limited, but Jia is each 100 mass ppm or less. This is because it can obtain a higher deformation inhibition effect.

The surface of the anode current collector 11 may be roughened or not coarsened. The roughened negative electrode current collector is, for example, a metal foil subjected to electrolytic treatment, embossing treatment or chemical etching. The negative electrode current collector that is not roughened is, for example, a rolled metal foil or the like.

[Negative electrode active material layer]

The negative electrode active material layer 12 contains the negative electrode active material of the present invention, and may further include other materials such as a negative electrode binder or a negative electrode conductive auxiliary agent in battery design. The negative electrode active material may contain a carbon-based active material or the like in addition to the negative electrode active material particles (lanthanum-based active material particles) containing a ruthenium compound (SiO _x : 0.5 ≦ x ≦ 1.6). The negative electrode active material for a nonaqueous electrolyte secondary battery of the present invention is a material constituting the negative electrode active material layer 12.

The ruthenium-based active material particles contained in the negative electrode active material of the present invention contain a ruthenium compound capable of occluding and releasing lithium ions.

As described above, the lanthanum active material particles contained in the negative electrode active material of the present invention contain a ruthenium compound (SiO _x : 0.5 ≦ x ≦ 1.6). As a composition of the ruthenium compound, it is preferred that x is close to one. This is because high cycle characteristics can be obtained. Further, the composition of the ruthenium material in the present invention does not necessarily mean that the purity is 100%, and a trace amount of an impurity element may be contained.

In addition, as described above, at least a part of the surface of the lanthanum-based active material particles contained in the negative electrode active material of the present invention is coated with a carbon film. Further, as described above, the carbon film is a specific surface area of the multi-point BET method measured from the ruthenium-based active material particles by a carbon-separating film, and is 5 m ² /g or more and 1000 m ² /g or less, and the self-decarburizing material particles are separated from the carbon. The compressive resistivity measured by the film is 1.0 × 10 ^-3 Ω ‧ cm or more and 1.0 Ω ‧ cm or less when compressed to a density of 1.0 g/cm ³ .

In this case, the carbon film is separated from the carbon-based film by the lanthanide-based active material particles, and the detached carbon film is added to the measurement container so that the mass per unit area becomes 0.15 g/cm ² , and then pressurized at 50 MPa. The compression density at the time of compression is preferably 1.0 g/cm ³ or more and 1.8 g/cm ³ or less. When the carbon coating film from which the ruthenium-based active material particles are separated satisfies the above-described compression density, the conductive auxiliary agent is easily entangled in the lanthanum-based active material particles when the negative electrode is formed, and the amount of adsorption of the binder is appropriately increased, so that the electrode can be used. The internal conductivity is excellent.

Further, the carbon film is preferably a type of type II or type III in which the adsorption-desorption isotherm is classified in the IUPAC classification in the adsorption-desorption isotherm of nitrogen measured from the ruthenium-based active material particles. . Since the adsorption-desorption isotherm measured by separating the carbon film is type II or III, the surface of the carbon film is non-porous. Therefore, when the negative electrode active material of the present invention is used to manufacture the negative electrode, the binder can be consumed. The suppression is minimal. In addition, since the binder is not excessively adsorbed on the surface of the negative electrode active material, the negative electrode active material containing the lanthanum-based active material particles having a large amount of expansion and contraction can be appropriately bonded.

As a method of separating the ruthenium-based active material particles from the carbon film, for example, the following separation method can be used. First, in Teflon (registered trademark) system In the beaker, lanthanum-based active material particles having a carbon film were added, and ion-exchanged water and ethanol were further added thereto, and the mixture was sufficiently stirred with a stirring bar made of Teflon (registered trademark). Then, hydrofluoric acid was added and stirred, nitric acid was added thereto, and ion-exchanged water was added as needed, and nitric acid was further added and allowed to stand for 3 hours. Then, the obtained black solution was filtered, whereby the separated carbon film was collected by filtration. Then, the carbon film which was separated from the film was washed with water, washed with ethanol, and dried under vacuum at 200 ° C for 10 hours. The thus-obtained detached carbon film can be used as a measurement target, and various analyses such as X-ray diffraction and Raman spectroscopy can be performed. Then, by performing various analyses on the separated carbon film, the influence of the ruthenium compound or the like of the core material is removed, and the characteristics of the pure carbon film can be measured.

The specific surface area of the carbon coating film from which the lanthanide-based active material particles are separated can be obtained by extrapolation from the adsorption isotherm at 4 or more points of the correlation coefficient R > 0.99.

The compressive resistivity of the carbon film which is separated from the bismuth-based active material particles can be measured, for example, under the following conditions.

‧Device: MCP-PD type of Mitsubishi Chemical ANALYTECH powder making resistance measuring system

‧4 probe method

‧Add: 0.30g

‧ Pressurization ‧ Measurement: The powder resistance was measured every 5 N, and the obtained measured value was extrapolated until the pressure was reduced to 20 N, and the compressive resistivity at 1.0 g/cm ³ was calculated.

Further, the adsorption-desorption isotherm system can be measured by desorbing nitrogen as an adsorbing molecule from an adsorbent (herein, a quinone-based active material particle). As the measuring device, BELSORP-mini manufactured by BEL Co., Ltd., Japan can be used. Furthermore, in the case of nitrogen absorption and desorption (history), the maximum difference in the amount of adsorption of nitrogen at the same pressure during adsorption and desorption is ΔV and the adsorption of nitrogen at p/p ⁰ = 0.9. When the amount V is compared, as long as it is ΔV/V ≦ 0.05, the experience is caused by the measurement error, and it is considered that there is substantially no experience, and the adsorption-desorption isotherm can be classified into type II or type III. Here, p/p ⁰ is the relative pressure, which is the equilibrium pressure divided by the saturated vapor pressure.

As a method of classifying the lanthanide active material particles which are classified into different adsorption isotherms, for example, when distinguishing lanthanide active material particles having a classification of type II and type IV, first, powder of lanthanide active material particles is used. Leave it in an environment with a humidity of 80% for 10 hours (3 or more times on the way). Next, in the cylindrical container, the powder was filled so that the bulk density became 5% with respect to the space in the cylindrical container, and after the cylindrical container was stirred for 2 hours, the cylindrical container was erected and allowed to stand and repeated twice. The operation is allowed to stand until the powder is piled up. In the obtained powder, a 20% portion (type II) deposited on the upper portion and a 20% portion (type IV) deposited on the lower side were separated, whereby the type II and type IV were distinguished.

Further, in the present invention, the true density of the carbon film on the surface of the lanthanum-based active material particles is preferably in the range of 1.2 g/cm ³ or more and 1.9 g/cm ³ or less. When the true density of the carbon film is 1.9 g/cm ³ or less, the carbon film on the surface of the lanthanum-based active material particles is not excessively dense, so that the electrolyte solution is easily impregnated into the ruthenium compound contained in the lanthanum-based active material particles, and the cycle characteristics or The battery characteristics such as initial charge and discharge characteristics are improved. In addition, when the true density is 1.2 g/cm ³ or more, the specific surface area of the lanthanum-based active material particles is an appropriate value, and when the negative electrode is produced, only the appropriate amount of the binder is adsorbed to improve the effect of the binder, and the battery characteristics are improved.

Here, the true density of the carbon film formed on the surface of the lanthanum-based active material particles is, for example, as shown in FIG. 2, the content of the carbon film (% by mass) and the density of the lanthanum-based active material particles are determined at several places. The extrapolation of the carbon film content in a substantially linear shape at a point of 100% by mass is obtained, and the true density of only the carbon film can be calculated. That is, the true density of the carbon film measured here is not measured and is measured.

Further, in the present invention, the carbon film formed on the surface of the lanthanum ^- based active material particles is preferably a Raman spectrum obtained by Raman spectroscopy, and has scattering peaks at 1330 cm ^-1 and 1580 cm ^-1 . satisfy their scattering peak intensity of _{0.7 <I 1330 / I 1580 <} 2.0 ratio I ₁₃₃₀ / I _1580. Thereby, the ratio of the carbon material having the diamond structure contained in the carbon film to the carbon material having the graphite structure can be optimized. As a result, when the negative electrode active material containing the above-described cerium-based active material particles having a carbon film is used as the negative electrode of the nonaqueous electrolyte secondary battery, a nonaqueous electrolyte secondary battery having excellent battery characteristics can be obtained.

Further, the Raman spectrum can be obtained by microscopic Raman analysis (ie, Raman spectroscopy), and according to the obtained Raman spectrum, the ratio of the carbon component having a diamond structure to the carbon component having a graphite structure can be obtained. . That is, the diamond Raman shift of 1330cm ^-1 is displayed sharp peaks in the graphite-based Raman shift of 1580 cm ^-1 show a sharp peak, in accordance with their intensity ratio, the carbon component can be easily obtained having a diamond structure and a graphite structure The proportion of carbon components. The diamond system has high strength, high density, and high insulation, and the graphite is excellent in electrical conductivity. Therefore, the carbon film which satisfies the above-described peak intensity ratio is optimized as described above, and as a result, electrode destruction due to expansion and ‧ shrinkage of the electrode material accompanying charging and discharging can be prevented, and a negative electrode having a conductive network can be obtained. Active substance.

In addition, the content of the carbon coating film is preferably 0.1% by mass or more and 25% by mass or less based on the lanthanum-based active material particles. The content of the carbon film is more preferably from 4% by mass to 20% by mass.

When the content is 0.1% by mass or more, the conductivity of the lanthanum-based active material particles can be surely improved. In addition, when the content ratio is 25% by mass or less, the battery characteristics are improved and the battery capacity is increased. The coating method of the carbon-based compound is not particularly limited, but is preferably a sugar carbonization method or a thermal decomposition method of a hydrocarbon gas. At this time, the carbon film is obtained by thermally decomposing the carbon-containing compound. By such a method, a carbon film containing a carbon material such as graphite can be formed. Moreover, as long as these methods are used, the coverage of the carbon coating on the surface of the lanthanum-based active material particles can be improved.

Moreover, in the present invention, the average thickness of the carbon coating film on the surface of the lanthanum-based active material particles is preferably 5 nm or more and 5000 nm or less. In particular, the average thickness of the carbon film is more preferably 5 nm or more and 500 nm or less. When the average thickness is 5 nm or more, sufficient conductivity is obtained, and as the conductivity is improved, the battery characteristics are improved. In addition, when the average thickness is 5,000 nm or less, the thickness of the carbon coating film is not excessively large with respect to the particle diameter of the lanthanum-based active material particles, and the ratio of the ruthenium compound in the high negative electrode active material can be maintained, and the non-aqueous electrolyte secondary battery can be used. The energy density is increased. Furthermore, as long as the average thickness is 500 nm or less, a higher negative electrode can be maintained. The ratio of the ruthenium compound in the active material. Further, the average thickness of the carbon coating film of the lanthanum-based active material particles can be determined by cross-sectional observation by FIB-TEM (Focused Ion Beam-Transmission Electron Microscope).

Further, in the present invention, the average coverage of the carbon film on the surface of the lanthanum-based active material particles is preferably 30% or more. When the average coverage ratio is 30% or more, the carbon component acts particularly effectively on the improvement of conductivity, and the battery characteristics are improved. In addition, the average coverage ratio is defined by the local composition analysis of SEM-EDX (Scanning Electron Microscope-Energy Dispersive X-ray Spectroscope), and is defined as the surface (carbon detection intensity) / (detection intensity of enthalpy).

Further, in the present invention, the carbon coating film on the surface of the lanthanum-based active material particle is a fragment of the _{Cy Hz-} based compound detected by TOF-SIMS, and a fragment of the _Cy- H _z- based compound is preferably used. At least a portion of the range that satisfies 6≧y≧2, 2y+2≧z≧2y-2 is detected. When the surface state of the compound fragment such as the _Cy H _z- based fragment is detected, the compatibility with the negative electrode binder such as CMC or polyimine is improved, and the battery characteristics are improved.

In this case, especially in the detection of carbon fragment _z C _y film based compound H, preferably in the TOF-SIMS-based C ₄ H ₉ detects the intensity of the D and C ₃ H ₅ detects the intensity E satisfies 2.5 ≧ D / E ≧0.3 relationship. When the ratio D/E of the above-described detection intensity is 2.5 or less, the surface resistance is small, so that the conductivity is improved and the battery characteristics are improved. In addition, when the ratio D/E of the above-mentioned detection intensity is 0.3 or more, the carbon film on the surface can be sufficiently formed, and the conductivity of the entire surface is improved by the carbon film, and the battery characteristics are improved. Further, the detected types and amounts of C _{y z} fragments based compound H, by changing the line may CVD conditions (gas temperature) and post-treatment conditions adjusted. The post-treatment mentioned here may be a baking treatment performed in a vacuum or an argon atmosphere, for example, at 950 to 1200 ° C after the CVD treatment.

The TOF-SIMS system can be measured, for example, under the following conditions.

PHI TRIFT 2 manufactured by ULVAC-PHI

‧One ion source: Ga

‧ sample temperature: 25 ° C

‧ Accelerating voltage: 5kV

‧ Point size: 100μm × 100μm

‧ Sputtering: Ga, 100μm × 100μm, 10s

‧ anion mass spectrum

‧ Sample: powder particles

Further, on the silicon-based active material silicon compound contained in the particles, as obtained from the chemical shift value of the ²⁹ spectra Si-MAS-NMR, administered at -20 ~ -74ppm amorphous silicon peak area A in area - The peak area B of the crystalline yttrium region and the lithium niobate region to be imparted at 75 to -94 ppm and the peak area C of the vermiculite region to be given at -95 to -150 ppm preferably satisfy the formula (1). Furthermore, the chemical shift is based on tetramethyl decane.

Formula (1): 5.0≧A/B≧0.01, 6.0≧(A+B)/C≧0.02

The higher the proportion of the amorphous ruthenium which suppresses the expansion accompanying the insertion of Li, the more the expansion of the negative electrode is suppressed and the cycle characteristics are improved as the battery is formed. In addition, as long as the range of the above formula (1) is satisfied, the proportion of the vermiculite component is small with respect to the antimony component such as amorphous germanium or crystalline germanium or the lithium niobate component such as Li ₂ SiO _{3 ,} and the antimony can be suppressed. The electron conductivity in the compound is lowered, so that the battery characteristics can be improved.

Further, the negative electrode active material of the present invention is obtained from the negative electrode active material particles, and the maximum of the crystalline yttrium region and the lithium niobate region which are obtained from the ²⁹ Si-MAS-NMR spectrum as a chemical shift value of -75 to -94 ppm. The peak intensity value H, and the peak intensity value I of the vermiculite region given as a chemical shift value of -95 to -150 ppm, preferably satisfy the relationship of H>I. When the SiO ₂ component is used as a reference, the amount of the lithium niobate component such as the cerium component or Li ₂ SiO ₃ may be sufficiently obtained as long as the SiO ₂ component is used. Improve the effect.

^{The 29} Si-MAS-NMR system can be measured, for example, under the following conditions.

²⁹ Si MAS NMR (Magic Angle Rotational Nuclear Magnetic Resonance)

‧Installation: 700 NMR splitter manufactured by Bruker

‧Probe: 50μL of 4mmHR-MAS rotor

‧ sample rotation speed: 10kHz

‧Measure the ambient temperature: 25 ° C

The median diameter of the lanthanum-based active material particles is not particularly limited, but is preferably 0.5 μm or more and 20 μm or less. In this case, as long as it is in this range, the storage and release of lithium ions during charging and discharging become easy, and the particles become difficult to be broken. Since the median diameter is 0.5 μm or more, the surface area does not increase, so that the irreversible capacity of the battery can be reduced. on the other hand, When the median diameter is 20 μm or less, the particles are less likely to be broken, and it is preferable that a new surface is less likely to occur.

Further, in the present invention, the half value width (2θ) of the diffraction peak due to the (111) crystal plane obtained by X-ray diffraction of the ruthenium compound contained in the ruthenium-based active material particles is preferably 1.2 or more. Further, the crystallite size due to the crystal face is preferably 7.5 nm or less. An anthracene compound having such a half-value width and a crystallite size is low in crystallinity. As described above, battery characteristics can be improved by using a ruthenium compound having low crystallinity and a small amount of Si crystals. Moreover, the formation of a stable Li compound can be carried out by the presence of such a low crystallinity compound.

Further, in the invention, it is preferred that Li is contained in at least a part of the lanthanum active material particles. In order to contain Li in the lanthanum active material particles, Li may be doped into the ruthenium compound. As a method of doping Li into the cerium compound, for example, a thermal doping method in which cerium-based active material particles and metal lithium are mixed and heated, or an electrochemical method can be mentioned. By including a Li compound in the ruthenium compound, the initial efficiency is improved. In addition, the initial efficiency of the negative electrode in the case of the nonaqueous electrolyte secondary battery is increased, and the balance between the positive electrode and the negative electrode during the cycle test is suppressed, and the maintenance ratio is improved.

In addition, when the lanthanum-based active material particles contain Li, at least one of Li ₂ SiO ₃ and Li ₄ SiO ₄ is preferably contained in at least a part of the lanthanum-based active material particles. As long as the lanthanum-based active material particles contain the above-described lithium niobate which is relatively stable as the Li compound, the stability of the slurry at the time of electrode production is further improved.

Further, as a method of doping Li into a ruthenium compound, A redox method can be used. In the modification by the redox method, for example, lithium is first inserted by impregnating the ruthenium compound particles in the solution A in which lithium is dissolved in an ether solvent. In the solution A, a polycyclic aromatic compound or a linear polyphenylene compound may be further contained. After the insertion of lithium, the active lithium is detached from the ruthenium compound particles by impregnating the ruthenium compound particles in the solution B containing the polycyclic aromatic compound or its derivative. As the solvent of the solution B, for example, an ether solvent, a ketone solvent, an ester solvent, an alcohol solvent, an amine solvent or a mixed solvent thereof can be used. Further, after being immersed in the solution B, by immersing the ruthenium compound particles in the solution C containing an alcohol solvent, a carboxylic acid solvent, water or a mixed solvent thereof, more active lithium ruthenium compound particles can be obtained. Get rid of. Further, instead of the solution C, a compound containing a ruthenium structure in a molecule as a solute may be used, and a solution C' containing an ether solvent, a ketone solvent, an ester solvent or a mixed solvent thereof as a solvent may be used. Further, the impregnation of the ruthenium compound particles in the solutions B, C, and C' may be repeated. As described above, as long as the active lithium is removed after the insertion of lithium, the negative electrode active material having higher water resistance is obtained. Then, it can be washed with an alcohol, an alkali water in which lithium carbonate is dissolved, a weak acid or pure water, or the like.

Further, the negative electrode active material (anthracene active material) of the present invention is produced by using a negative electrode comprising a mixture of the lanthanoid active material and a carbon active material, and a test battery made of counter lithium. The charge and discharge which are generally caused by the discharge of lithium by the insertion of lithium into the lanthanum-based active material, and the discharge of the current from the ruthenium-based active material by a lithium-like current, are plotted 30 times, and the discharge is shown in a graph. The capacity Q is used to differentiate the potential V of the negative electrode based on the polar lithium. In the case where the relationship dQ/dV is related to the potential V, the potential V of the negative electrode preferably has a peak in the range of 0.40 V to 0.55 V during the discharge of the Xth time (1≦X≦30). The above-mentioned peak system in the -dQ/dV curve is similar to the peak of the ruthenium material, and since the discharge curve on the high potential side is more sharply erected, it becomes easy to exhibit capacity when performing battery design. In addition, as long as the negative electrode active material exhibiting the above peaks during charge and discharge within 30 times, it can be determined that the whole is stable.

Examples of the negative electrode conductive auxiliary agent include graphite such as carbon black, acetylene black, and flaky graphite, and carbon materials (carbon-based materials) such as Ketjen black, carbon nanotubes, and carbon nanofibers. Any one or more. These conductive auxiliary agents are preferably those having a smaller median diameter than the cerium compound.

In the present invention, the negative electrode active material layer 12 of Fig. 1 may further contain carbon-based active material particles in addition to the negative electrode active material of the present invention. Thereby, the electric resistance of the negative electrode active material layer 12 containing the negative electrode active material of the present invention can be lowered, and the expansion stress accompanying charging can be alleviated. Examples of the carbon-based active material include pyrolytic carbons, cokes, glassy carbon fibers, organic polymer compound fired bodies, and carbon blacks. Among them, the carbon-based active material particles are preferably graphite materials. The graphite material exhibits a better initial efficiency and capacity retention ratio than other carbon-based active material particles.

Furthermore, in the present invention, the mass ratio of the lanthanum-based active material particles is preferably 5% by mass or more based on the total mass of the lanthanum-based active material particles and the carbon-based active material particles. Further, the mass ratio of the lanthanum-based active material particles is more preferably less than 90% by mass. As long as it is contained in such a ratio When the negative electrode active material of the lanthanum active material particles is used in a negative electrode of a nonaqueous electrolyte secondary battery, good initial efficiency and capacity retention ratio can be obtained. Of course, even if the mass ratio of the lanthanoid active material particles is 90% by mass or more and 100% by mass or less, a high battery capacity, good cycle characteristics, and good initial charge and discharge characteristics can be obtained by using the negative electrode active material of the present invention.

Further, the average particle diameter F of the lanthanum-based active material particles is preferably such that the average particle diameter G of the carbon-based active material particles satisfies the relationship of 25 ≧G/F ≧ 0.5. In other words, the average particle diameter of the carbon-based active material particles is preferably equal to or larger than the average particle diameter of the lanthanum-based active material particles. In this case, when the active material particles of the lanthanum-based active material particles are expanded to the same extent as the carbon-based active material particles by the expansion and contraction of the Li insertion and the detachment, the destruction of the composite material layer can be prevented. When the carbon-based active material particles become larger than the lanthanum-based active material particles, the volume density of the negative electrode during charging and the initial efficiency are improved, and the battery energy density is improved.

The negative electrode active material layer 12 of Fig. 1 is formed, for example, by a coating method. The coating method is a method in which the lanthanum-based active material particles, the above-mentioned binder, and the like, and, if necessary, a conductive auxiliary agent or a carbon-based active material particle are mixed and dispersed in an organic solvent or water.

[Manufacturing method of negative electrode]

A method of producing the negative electrode of the present invention will be described.

First, a method of producing a negative electrode material contained in a negative electrode will be described. First, a ruthenium compound represented by SiO _x (0.5 ≦ x ≦ 1.6) was produced. Next, the surface of the ruthenium compound is coated with a carbon film. Here, by inserting Li into the ruthenium compound, a Li compound can be formed on the surface or inside of the ruthenium compound or both, and the ruthenium compound can be modified.

Then, a part of the particles of the ruthenium compound coated with the carbon film was taken out, and the particles of the ruthenium compound taken out were separated from the carbon film, and the specific surface area and the compression specific resistance were measured. Then, the carbon film satisfying the following conditions: a specific surface area of the multi-point BET method measured by separating the carbon film is 5 m ² /g or more and 1000 m ² /g or less, and the compression resistivity measured by separating the carbon film is compressed. When the density is 1.0 g/cm ³ , it is 1.0 × 10 ^-3 Ω ‧ cm or more and 1.0 Ω ‧ cm or less, and particles of the ruthenium compound coated with the carbon film are selected as the negative electrode active material particles.

More specifically, the negative electrode material can be produced, for example, by the following procedure.

First, a raw material (gasification starting material) which generates cerium oxide gas is heated in a temperature range of 900 ° C to 1600 ° C in the presence of an inert gas or under reduced pressure to generate cerium oxide gas. At this time, the raw material is a mixture of the metal cerium powder and the cerium oxide powder. If the surface oxygen of the metal cerium powder and the trace oxygen in the reaction furnace are considered, the molar molar ratio is preferably 0.8<metal cerium powder/cerium oxide. Powder <1.3 range. The Si microcrystals in the particles are controlled by the addition range or the change of the vaporization temperature and the heat treatment after the formation. The resulting gas system is deposited on the adsorption plate. When the temperature in the reactor is lowered to 100 ° C or lower, the deposit is taken out and pulverized and powdered using a ball mill, a jet mill or the like.

Secondly, carbon coating is coated on the surface of the obtained powder material. membrane. As a method of forming a carbon film on the surface of the obtained powder material, thermal CVD is preferred. In thermal CVD, a powder material is placed in the furnace to fill the hydrocarbon gas to increase the temperature inside the furnace. The decomposition temperature is not particularly limited, but is particularly preferably 1200 ° C or lower, and particularly preferably 950 ° C or lower, and it is possible to suppress accidental unevenness of particles of the ruthenium compound.

When the carbon film is formed by thermal CVD, the specific surface area and the compressive resistivity of the particles of the ruthenium compound from the carbon film can be adjusted by adjusting the CVD temperature, time, and powder material (矽 compound powder) during CVD. Controlled by agitation. Further, the amount of the carbon film, the thickness, the coverage, and the adsorption and desorption isotherms at the time of the particle separation from the carbon film of the ruthenium compound can also be adjusted by adjusting the CVD temperature, time, and powder material during CVD (矽Controlled by the agitation of the compound powder). Further, by adjusting the temperature in the furnace, the peak intensity ratio I ₁₃₃₀ /I ₁₅₈₀ in the Raman spectrum can be adjusted. Further, the density of the carbon film and the compression density when the particles of the ruthenium compound are separated from the carbon film can be controlled by adjusting the gas flow rate during CVD.

Next, a part of the particles of the ruthenium compound coated with the carbon film is taken out, for example, by using the above-described method for separating the carbon film, the specific surface area, and the measurement of the compressive resistivity, the particles of the ruthenium compound taken out are separated from the carbon film, and then measured. Specific surface area and compressive resistivity. Also, taken the following condition is satisfied carbon film: single measured ex carbon film multi-point BET specific surface area Law of 5m ² / g or more 1000m ² / g or less, and the isolated carbon film measured compression resistivity based on When it is compressed to a density of 1.0 g/cm ³ , it is 1.0 × 10 ^-3 Ω ‧ cm or more and 1.0 Ω ‧ cm or less, and particles of a ruthenium compound coated with the carbon film are selected as negative electrode active material particles.

Further, the selection of the particles of the above-described ruthenium compound is not necessarily required to be carried out for each production of the negative electrode material, and it is selected as long as the production conditions of the carbon film satisfying the following conditions are found: a plurality of points measured by separating the carbon film The specific surface area of the BET method is 5 m ² /g or more and 1000 m ² /g or less, and the compressive resistivity measured by separating the carbon film is 1.0 × 10 ^-3 Ω · ‧ cm or more when compressed to a density of 1.0 g / cm ³ Below 1.0 Ω ‧ cm, the negative electrode material can be subsequently fabricated under the same conditions as the selected conditions.

The particles of the ruthenium compound having a carbon film thus selected are used as the negative electrode active material particles to prepare a negative electrode material for a nonaqueous electrolyte secondary battery.

Next, other materials such as the negative electrode active material particles, the negative electrode binder, and the conductive auxiliary agent are mixed to form a negative electrode mixture, and then an organic solvent, water, or the like is added to form a slurry.

Next, a slurry of the negative electrode mixture is applied onto the surface of the negative electrode current collector, and dried to form the negative electrode active material layer 12 shown in FIG. At this time, heat and pressure may be performed as needed. The negative electrode can be manufactured in this manner.

Further, when a carbon-based material having a median diameter smaller than that of the lanthanide-based active material particles is added as a conductive auxiliary agent, for example, acetylene black can be added and added.

The hydrocarbon gas system is not particularly limited, but is preferably 3 ≧ n among the C _n H _m compositions. This is because the manufacturing cost can be reduced and the physical properties of the decomposition product are good.

<2. Lithium ion secondary battery>

Next, a lithium ion secondary battery containing the negative electrode active material of the present invention will be described.

[Composition of laminated thin film type lithium ion secondary battery]

The laminated film type secondary battery 20 shown in FIG. 3 mainly includes a wound electrode body 21 housed inside the sheet-like exterior member 25. This winding system has a separator between the positive electrode and the negative electrode and is wound up. Further, a separator is provided between the positive electrode and the negative electrode, and a laminate is also accommodated. In any of the electrode bodies, the positive electrode lead 22 is attached to the positive electrode and the negative electrode lead 23 is attached to the negative electrode. The outermost peripheral portion of the electrode body is protected by a protective tape.

The positive and negative electrode leads are led out from the inside of the exterior member 25 toward the outside, for example, in one direction. The positive electrode lead 22 is formed of a conductive material such as aluminum, and the negative electrode lead 23 is formed of a conductive material such as nickel or copper.

The exterior member 25 is, for example, a laminated film in which a vulcanized layer, a metal layer, and a surface protective layer are laminated in this order, and the laminated film is formed by adhering the molten adhesive layer to the electrode body 21 in a manner opposite to each other. The outer peripheral edge portions of the melted layer of the film are bonded to each other or by an adhesive or the like. The fusion bonded portion is, for example, a film of polyethylene or polypropylene, and the metal portion is an aluminum foil or the like. The protective layer is, for example, nylon or the like.

The adhesive film 24 is inserted between the exterior member 25 and the positive and negative electrode leads in order to prevent intrusion of outside air. This material is, for example, polyethylene, polypropylene, or polyolefin resin.

[positive electrode]

The positive electrode has a positive electrode active material layer on both surfaces or one surface of the positive electrode current collector, for example, similarly to the negative electrode 10 of FIG. 1 .

An example of the positive electrode current collecting system is formed of a conductive material such as aluminum.

The positive electrode active material layer may contain any one or two or more kinds of positive electrode materials capable of occluding and releasing lithium ions, and may include other materials such as a binder, a conductive auxiliary agent, and a dispersing agent as designed. In this case, the details of the binder and the conductive auxiliary agent are, for example, the same as the above-described negative electrode binder and negative electrode conductive auxiliary agent.

As the positive electrode material, a lithium-containing compound is preferable. Examples of the lithium-containing compound include a composite oxide composed of lithium and a transition metal element, or a phosphoric acid compound having lithium and a transition metal element. Among these positive electrode materials, at least one or more compounds of nickel, iron, manganese, and cobalt are preferable. As such a chemical formula, it is represented, for example, by Li _x M ₁ O ₂ or Li _y M ₂ PO ₄ . In the formula, M ₁ and M _{2 each} represent at least one transition metal element. The values of x and y indicate different values depending on the state of charge and discharge of the battery, but are generally expressed by 0.05 ≦ x ≦ 1.10 and 0.05 ≦ y ≦ 1.10.

Examples of the composite oxide having a lithium and a transition metal element include a lithium cobalt composite oxide (Li _x CoO ₂ ) and a lithium nickel composite oxide (Li _x NiO ₂ ) as a phosphoric acid compound having lithium and a transition metal element. For example, a lithium iron phosphate compound (LiFePO ₄ ) or a lithium iron manganese phosphate compound (LiFe _1-u Mn _u PO ₄ (u<1)) or the like can be given. When such a positive electrode material is used, a high battery capacity can be obtained, and excellent cycle characteristics can be obtained.

[negative electrode]

The negative electrode has the same configuration as the negative electrode 10 for a lithium ion secondary battery of FIG. 1 described above. For example, the negative electrode active material layer 12 containing the negative electrode active material of the present invention is provided on both surfaces of the current collector 11 . The negative electrode is preferably one in which the negative electrode charging capacity is increased with respect to the electric capacity (as the charging capacity of the battery) obtained from the positive electrode active material agent. This is to suppress the precipitation of lithium metal on the negative electrode.

The positive electrode active material layer is provided on a part of both surfaces of the positive electrode current collector, and the negative electrode active material layer is also provided on a part of both surfaces of the negative electrode current collector. At this time, for example, the negative electrode active material layer provided on the negative electrode current collector is provided with a region where the opposing positive electrode active material layer does not exist. This is for a stable battery design.

In the non-opposing region, that is, in the region where the negative electrode active material layer and the positive electrode active material layer are not opposed, the charge and discharge are hardly affected. Therefore, the state of the negative electrode active material layer is maintained as it is, and the composition of the negative electrode active material or the like can be used to accurately investigate the composition and the like without depending on the presence or absence of charge and discharge.

[separator]

The separator isolates the positive electrode and the negative electrode, and allows lithium ions to pass while preventing short-circuiting of the current accompanying the contact between the two electrodes. This separator is formed, for example, by a porous film made of synthetic resin or ceramics, and may have two or more kinds of pores. A laminated structure synthesized by a layer of a plasma membrane. Examples of the synthetic resin include polytetrafluoroethylene, polypropylene, polyethylene, and the like.

[electrolyte]

At least a portion of the active material layer or the separator is impregnated with a liquid electrolyte (electrolyte). This electrolyte solution dissolves an electrolyte salt in a solvent, and may contain other materials such as an additive.

As the solvent, for example, a nonaqueous solvent can be used. Examples of the nonaqueous solvent include the following materials: ethyl carbonate, propyl carbonate, butyl carbonate, dimethyl carbonate, diethyl carbonate, ethyl methyl carbonate, methyl propyl carbonate, 1,2-dimethoxyethane or tetrahydrofuran.

Among them, at least one of ethyl carbonate, propylene carbonate, dimethyl carbonate, diethyl carbonate, and ethyl methyl carbonate is preferably used because more excellent properties can be obtained. Further, in this case, by combining a high viscosity solvent such as ethyl carbonate or propylene carbonate with a low viscosity solvent such as dimethyl carbonate, ethyl methyl carbonate or diethyl carbonate, more excellent properties can be obtained. This is to improve the dissociation or ion mobility of the electrolyte salt.

As the solvent additive, it is preferred to contain an unsaturated carbon-bonded cyclic carbonate. This is because a stable film is formed on the surface of the negative electrode during charge and discharge, and the decomposition reaction of the electrolytic solution can be suppressed. Examples of the unsaturated carbon-bonded cyclic carbonate include carbonic acid-extended vinyl ester or vinyl carbonate-extended ethyl ester.

Further, as the solvent additive, sultone (cyclic sulfonate) is preferably contained because the chemical stability of the battery is improved. Sulfene Examples of the ester include propane sultone and propylene sultone.

Further, the solvent preferably contains an acid anhydride because the chemical stability of the electrolytic solution is improved. Examples of the acid anhydride include propane disulfonic acid anhydride.

The electrolyte salt may contain, for example, any one or more of light metal salts such as lithium salts. Examples of the lithium salt include lithium hexafluorophosphate (LiPF ₆ ), lithium tetrafluoroborate (LiBF ₄ ), and the like.

The content of the electrolyte salt is preferably 0.5 mol/kg or more and 2.5 mol/kg or less with respect to the solvent, because high ion conductivity can be obtained.

[Manufacturing method of laminated thin film type lithium ion secondary battery]

Initially, a positive electrode using the above positive electrode material was produced. First, a positive electrode active material and an optional binder, a conductive auxiliary agent, and the like are mixed to form a positive electrode mixture, and then dispersed in an organic solvent to form a positive electrode mixture slurry. Then, the mixture slurry is applied onto the positive electrode current collector by a coating device such as a knife roll or a die coater having a die, and dried by hot air to obtain a positive electrode active material layer. Finally, the positive electrode active material layer is compression-molded by a roll press or the like. At this time, heating can be performed, and compression and heating can be repeated several times.

Next, using the same operation procedure as that of the above-described negative electrode 10 for lithium ion secondary battery, a negative electrode active material layer was formed on the negative electrode current collector to prepare a negative electrode.

The positive electrode and the negative electrode were produced by the same production procedure as described above. At this time, respective activities are formed on both sides of the positive electrode and the negative electrode collector. Material layer. At this time, in any of the electrodes, the application length of the active material on both faces may be different (see Fig. 1).

Next, adjust the electrolyte. Continuing, the positive electrode lead 22 is attached to the positive electrode current collector by ultrasonic welding or the like, and the negative electrode lead 23 is attached to the negative electrode current collector. Next, the positive electrode and the negative electrode were laminated via a separator, or wound to form a wound electrode body, and the protective tape was attached to the outermost peripheral portion (see FIG. 3). Next, the wound body is formed in a flat shape. Then, after the wound electrode body is sandwiched between the folded film-shaped exterior members 25, the insulating portions of the exterior member are then thermally opened and sealed in a state in which only one direction is opened. A flexible electrode body. The adhesive film 24 is inserted between the positive electrode lead 22 and the negative electrode lead 23 and the exterior member 25. A predetermined amount of the electrolyte adjusted as described above was introduced from the open portion to perform vacuum impregnation. After impregnation, the open portion is followed by vacuum hot melt bonding.

As described above, the laminated film type secondary battery 20 can be manufactured.

[Examples]

Hereinafter, the present invention will be more specifically described by showing examples and comparative examples of the present invention, but the present invention is not limited by the examples.

(Example 1-1)

The laminated film type secondary battery 20 shown in Fig. 3 was produced by the following procedure.

The positive electrode was originally produced. The mixed positive electrode active material was 95 parts by mass of LiCoO ₂ of the lithium cobalt composite oxide, 2.5 parts by mass of the positive electrode conductive auxiliary agent (acetylene black), and 2.5 parts by mass of the positive electrode binder (polyvinylidene fluoride, PVDF) to form a positive electrode mixture. Next, the positive electrode mixture was dispersed in an organic solvent (N-methyl-2-pyrrolidone, NMP) to form a paste-like slurry. Further, the slurry was applied to both sides of the positive electrode current collector by a coating device having a die, and dried by a hot air drying device. At this time, the positive electrode current collecting system used was a thickness of 15 μm. Finally, compression molding is carried out by rolling.

Next, a negative electrode was produced. In order to produce a negative electrode active material, first, a raw material in which metal ruthenium and ruthenium dioxide are mixed is placed in a reaction furnace, and it is deposited under a vacuum of 10 Pa, and after sufficiently cooled, the deposit is taken out and pulverized by a ball mill. After the particle diameter is adjusted, a carbon film is obtained by performing thermal CVD. At this time, a rotary kiln type reaction furnace was used in the thermal CVD, and the carbon source was methane gas. The temperature in the furnace was set at 1000 ° C, the pressure was set at 1 atm, and the CVD time was set at 6 hours.

The prepared powder was subjected to an electrochemical method using a 1:1 mixed solvent of propylene carbonate and ethyl carbonate (containing 1.3 mol/kg of lithium hexafluorophosphate (LiPF ₆ ) as an electrolyte salt). Upgraded. The resulting material was dried in a carbonic acid environment.

Then, a part of the powder obtained as described above was taken out, placed in a beaker of Teflon (registered trademark), and ion-exchanged water and ethanol were further added thereto, and the mixture was stirred well with a stir bar made of Teflon (registered trademark). Then, hydrofluoric acid was added, stirred, nitric acid was added, ion-exchanged water was added as needed, nitric acid was further added, and it left for 3 hours. Then, the separated carbon film was filtered by filtering the obtained black solution. Next, the carbon film which was separated from the film was washed with water, washed with ethanol, and dried under vacuum at 200 ° C for 10 hours. The specific surface area of the multi-point BET method of the thus separated carbon film and the compression resistivity when compressed to a density of 1.0 g/cm ³ were measured.

As a result, the specific surface area of the multi-point BET method of the separated carbon film was 180 m ² /g, and the compression resistivity at a density of 1.0 g/cm ³ was 8.0 × 10 ^-3 Ω ‧ cm.

Next, the precursor of the negative electrode active material and the negative electrode binder (polyglycolic acid) and the conductive auxiliary agent 1 (scaly graphite) and the conductive auxiliary agent 2 (acetylene black) are mixed at a dry mass ratio of 80:8:10:2. Thereafter, it was diluted with water to form a paste-like negative electrode mixture slurry. At this time, water was used as a solvent for polyacrylic acid. Next, the negative electrode mixture slurry was applied to both surfaces of the negative electrode current collector by a coating device, and then dried. As this negative electrode current collector, an electrolytic copper foil (thickness = 15 μm) was used. Finally, it was dried at 90 ° C for 1 hour in a vacuum atmosphere.

Subsequently, after mixing a solvent (4-fluoro-1,3-dioxolan-2-one (FEC)), ethyl carbonate (EC) and dimethyl carbonate (DMC), an electrolyte salt (hexafluorocarbon) is obtained. Lithium phosphate: LiPF ₆ ) was dissolved to prepare an electrolyte. At this time, the composition of the solvent was made to be FEC:EC:DMC=10:20:70 by volume ratio, and the content of the electrolyte salt was 1.2 mol/kg with respect to the solvent.

Next, the secondary battery was assembled as follows. Initially, at one end of the positive electrode current collector, the aluminum wire is ultrasonically welded, and the nickel wire is welded to the negative electrode current collector. Further, the positive electrode, the separator, the negative electrode, and the separator were laminated in this order to obtain a wound electrode body wound in the longitudinal direction. The end portion of the winding was fixed with PET protective tape. In the separator, a laminate film obtained by sandwiching a film having porous polypropylene as a main component on a film containing porous polyethylene as a main component was used in a thickness of 12 μm. Next, sandwich the electrode between the exterior members After the body is removed, the outer peripheral portions are thermally fused to each other, and the electrode body is housed inside. The exterior member is an aluminum laminate film synthesized by laminating a nylon film, an aluminum foil, and a polypropylene film. Next, the adjusted electrolytic solution is injected from the opening, and after being impregnated in a vacuum atmosphere, it is thermally fused and closed.

(Example 1-2 to Example 1-5, Comparative Example 1-1 to Comparative Example 1-2)

A secondary battery was produced in the same manner as in Example 1-1, except that the amount of oxygen was adjusted in the ruthenium compound represented by SiO _x .

The lanthanide active material particles in Examples 1-1 to 1-5 and Comparative Examples 1-1 to 1-2 all had the following physical properties. The peak area ratio measured by ²⁹ Si-MAS-NMR of the ruthenium compound contained in the lanthanide active material particles was A/B = 0.6, and (A + B) / C = 0.32. Further, the median diameter D ₅₀ of the lanthanoid active material particles was 5.1 μm. The half value width (2θ) of the diffraction peak due to the Si (111) crystal plane obtained by X-ray diffraction was 1.85°, and the crystallite size of the crystal face Si(111) was 4.62 nm.

Further, in Examples 1-1 to 1-5, Comparative Examples 1-1 to 1-2, the content of the carbon film was 5%, and the average thickness of the carbon film was 110 nm, and the average coverage of the carbon film. At 90%, the true density of the carbon film is 1.6 g/cm ³ . In addition, the intensity of the Raman spectrum is I ₁₃₃₀ /I ₁₅₈₀ =1.1. Further, a fragment of a _Cy H _z -based compound of y = 2, 3, 4, z = 2y-3, 2y-1, 2y+1 was detected by TOF-SIMS. Further, the intensity ratio of the detection intensity D of C ₄ H _{9 to} the detection intensity E of C ₃ H ₅ by TOF-SIMS was D/E (Int(C ₄ H ₉ /C ₃ H ₅ ))=0.8.

Further, the specific surface area of the multi-point BET method of the separated carbon film was 180 m ² /g, and the compression resistivity at a density of 1.0 g/cm ³ was 8.0 × 10 ^-3 Ω · cm. Also, the adsorption-desorption isotherm of the detached carbon film has the characteristics of type II in the IUPAC classification. In addition, when the mass of the carbon film per unit area was 0.15 g/cm ² , the separated carbon film was placed in a measurement container, and the compression density at the time of compression at 50 MPa was 1.1 g/cm ³ .

When the cycle characteristics (maintenance %) and the initial charge and discharge characteristics (initial efficiency %) of the secondary batteries of Examples 1-1 to 1-5 and Comparative Examples 1-1 to 1-2 were investigated, the table was obtained. The result shown in 1.

Regarding the cycle characteristics, the investigation is as follows. First, in order to stabilize the battery, two cycles of charge and discharge were performed in an environment of 25 ° C, and the discharge capacity of the second cycle was measured. Next, charging and discharging were performed until the total number of cycles became 100 cycles, and each discharge capacity was measured. Finally, the discharge capacity of the 100th cycle was divided by the discharge capacity of the second cycle (x100 for %), and the capacity retention ratio was calculated. As a circulation condition, charging was performed at a constant current density of 2.5 mA/cm ² until reaching 4.3 V, and at a stage where the voltage was reached, it was charged at a constant voltage of 4.3 V until the current density reached 0.25 mA/cm ² . Further, during discharge, the battery was discharged at a constant current density of 2.5 mA/cm ² until the voltage reached 3.0 V.

When the initial charge and discharge characteristics were investigated, the initial efficiency (%) = (first discharge capacity / initial charge capacity) × 100 was calculated. The ambient temperature is the same as when investigating the cycle characteristics. The charge and discharge conditions were carried out at 0.2 times the cycle characteristics. That is, it is charged at a constant current density of 0.5 mA/cm ² until reaching 4.3 V, and at a voltage of 4.3 V, it is charged at a constant voltage of 4.3 V until the current density reaches 0.05 mA/cm ² , and the discharge is 0.5 mA. The constant current density of /cm ² is discharged until the voltage reaches 3.0V.

In addition, the maintenance ratio and the primary efficiency shown in the following Tables 1 to 9 do not contain a carbon-based active material such as natural graphite (for example, a median diameter of 20 μm), and only a ruthenium compound having a carbon film is used as a negative electrode. The maintenance rate and the initial efficiency of the active material show the maintenance rate and initial efficiency of the ruthenium compound. Thereby, it is possible to measure the change in the maintenance rate and the initial efficiency depending only on the change (the amount of oxygen, the crystallinity, the change in the median diameter, etc.) of the ruthenium compound or the change (content ratio, composition, etc.) of the carbon film.

[Table 1] NMR: A/B = 0.6, (A + B) / C = 0.32, D ₅₀ = 5.1 μm, Si (111) half value width θ = 1.85 ° Microcrystals 4.62 nm

Carbon film content rate 5%, carbon film average coverage rate 90%, carbon film average thickness 110nm, Raman I ₁₃₃₀ /I ₁₅₈₀ =1.1, carbon film true density = 1.6g/cm ³ , carbon film adsorption isotherm type: II Type, carbon film specific surface area = 180 m ² /g, carbon film compression resistivity (1.0 g/cm ³ ) = 8.00 × 10 ^-3 Ω ‧ cm, carbon film compression density (50 MPa) = 1.1 g / cm ³ , TOF -SIMS C _y H _z y=2,3,4 z=2y-3, 2y-1, 2y+1 Int(C ₄ H ₉ /C ₃ H ₅ )=0.8, FEC:EC:DMC=1:2 :7,LIPF ₆ 1.2mol/kg, positive LiCoO ₂ , negative electrode binder PAA, active material ratio: lanthanum active material particles 100%

As shown in Table 1, in the ruthenium compound represented by SiO _x , when the value of x was outside the range of 0.5 ≦ x ≦ 1.6, the battery characteristics were deteriorated. For example, as shown in Comparative Example 1-1, when oxygen is insufficient (x = 0.3), although the initial efficiency is improved, the capacity retention rate is remarkably deteriorated. On the other hand, as shown in Comparative Example 1-2, when the amount of oxygen was large (x = 1.8), the conductivity was lowered, and the maintenance rate and the initial efficiency were also lowered, and the measurement was impossible.

(Example 2-1 to Example 2-3, Comparative Example 2-1 to Comparative Example 2-3)

In addition to changing the state of the carbon coating film coated on the surface of the cerium compound, the compression resistivity when compressed to a density of 1.0 g/cm ³ as measured by the carbon-separated film, and the mass per unit area were 0.15 g/cm ² . After the method was added to the inside of the measurement container, the secondary battery was produced in the same manner as in Example 1-3 except that the compression density at the time of compression was 50 MPa. Further, when the ruthenium compound is measured by the carbon film, the compression resistivity and the compression density of the carbon film are adjusted by the CVD temperature, time, and the agitation of the powder material (矽 compound powder) and the CVD gas flow rate during CVD. And proceed.

When the cycle characteristics and the initial charge and discharge characteristics of the secondary batteries of Examples 2-1 to 2-3 and Comparative Examples 2-1 to 2-3 were investigated, Table 2 was obtained. The results shown in .

[Table 2] SiO _x (x = 0.9), NMR: A / B = 0.6 (A + B) / C = 0.32, D ₅₀ = 5.1 μm, Si (111) half value width θ = 1.85 ° Microcrystals 4.62 nm

Carbon film content rate 5%, carbon film average coverage rate 90%, carbon film average thickness 110nm, Raman I ₁₃₃₀ /I ₁₅₈₀ =1.1, carbon film true density = 1.6g/cm ³ , carbon film adsorption isotherm type: II Type, carbon film specific surface area = 180 m ² /g, TOF-SIMS y = 2, 3, 4 z = 2y-3, 2y-1, 2y + 1 Int (C ₄ H ₉ / C ₃ H ₅ ) = 0.8, FEC: EC: DMC = 1:2:7, LIPF ₆ 1.2 mol/kg, positive LiCoO ₂ , negative electrode binder PAA, active material ratio: lanthanide active material particles 100%

As shown in Table 2, when the density of the carbon film is 1.0 g/cm ³ , the compression resistivity is 1.0 × 10 ^-3 Ω ‧ cm or more and 1.0 Ω ‧ cm or less, and the electron conductivity at the time of charge and discharge is appropriate. On the other hand, it is difficult to cause precipitation of Li or the like, and the conductivity of the negative electrode is easily changed uniformly, and the maintenance ratio and the initial efficiency are improved. In the case where the compression density of the carbon film is 1.0 g/cm ³ or more and 1.8 g/cm ³ or less, the binder is appropriately adsorbed on the surface of the ruthenium compound, and the initial efficiency and the capacity retention ratio are improved.

(Example 3-1 to Example 3-8, Comparative Example 3-1 to Comparative Example 3-2)

In addition to changing the content of the carbon film relative to the lanthanum active material particles, the average thickness of the carbon film on the surface of the ruthenium compound, the average coverage of the carbon film on the surface of the ruthenium compound, the average true density of the surface of the ruthenium compound, and the detachment The secondary battery was produced in the same manner as in Example 1-3, except that the IUPAC classification of the adsorption and desorption isotherms of the carbon film and the specific surface area of the separated carbon film were carried out. The content of the carbon film, the average thickness, the average coverage, the average true density, the IUPAC classification of the adsorption-desorption isotherm of the detached carbon film, and the change in the specific surface area of the detached carbon film can be adjusted by adjusting The CVD temperature, time, and agitation of the cerium compound powder at the time of CVD are controlled.

When the cycle characteristics and the initial charge and discharge characteristics of the secondary batteries of Examples 3-1 to 3-8 and Comparative Examples 3-1 to 3-2 were investigated, the results shown in Table 6 were obtained.

[Table 3] SiO _x (x = 0.9), NMR: A / B = 0.6 (A + B) / C = 0.32, D ₅₀ = 5.1 μm, Si (111) half value width θ = 1.85 ° Microcrystals 4.62 nm , carbon film Raman I ₁₃₃₀ / I ₁₅₈₀ = 1.1, carbon film compression resistivity (1.0g / cm ³ ) = 8.00 × 10 ^-3 Ω ‧ cm, carbon film compression density (50MPa) = 1.1g / cm ³ , TOF-SIMS C _y H _z y=2,3,4 z=2y-3, 2y-1, 2y+1 Int(C ₄ H ₉ /C ₃ H ₅ )=0.8, FEC:EC:DMC=1: 2:7 LIPF ₆ 1.2mol/kg, positive LiCoO ₂ , negative electrode binder PAA, active material ratio: lanthanide active material particles 100%

As can be seen from Table 3, in Example 3-1 to Example 3-8 in which the specific surface area of the separated carbon film was 5 m ² /g or more and 1000 m ² /g or less, comparison with Comparative Example 3-1 was obtained. Example 3-2 has better battery characteristics. This is because when the specific surface area of the detached carbon film is less than 5 m ² /g, the impregnation property of the electrolyte is lowered, and the specific surface area of the detached carbon film exceeds 1000 m ² /g, due to excessive adsorption of the binder. The adhesiveness is lowered and the battery characteristics are deteriorated.

Further, in the examples, the content of the carbon film was completely satisfied to be 0.1% to 25%, the thickness of the carbon film was 5 nm or more and 500 nm or less, the average coverage was 30% or more, and the true density of the carbon film was 1.2 g/cm ³ or more. Examples 1-3 and Examples 3-3 to 3-6 in which the g/cm ³ or less, and the IUPAC adsorption-desorption isotherms of the separated carbon film are classified into the type II or III conditions, The system can get the best battery characteristics. On the other hand, when one or more of these conditions are not satisfied, the battery characteristics are deteriorated somewhat in comparison with Examples 1-3 and 3-3 to 3-6.

(Example 4-1 to Example 4-6)

The secondary battery was produced in the same manner as in Example 1-3, except that the ratio of the Si component to the SiO ₂ component (the ratio of Si to vermiculite) and the degree of unevenness were changed. The ratio of the Si component to the SiO ₂ component was changed in Examples 4-1 to 4-6 by changing the amount of metal ruthenium and vermiculite added during SiO production. Further, in the ruthenium compound (SiO _x ), as the chemical shift value obtained from the ²⁹ Si-MAS-NMR spectrum, the peak area A of the amorphous yttrium (a-Si) region given at -20 to -74 ppm is The ratio A/B of the peak area B of the crystalline cerium (c-Si) region imparted at -75 to -94 ppm is adjusted by controlling the degree of unevenness by heat treatment.

When the cycle characteristics and the initial charge and discharge characteristics of the secondary batteries of Examples 4-1 to 4-6 were investigated, the results shown in Table 4 were obtained.

[Table 4] SiO _x (x = 0.9), D ₅₀ = 5.1 μm, Si (111) half value width θ = 1.85 ° crystallite 4.62 nm, carbon film Raman I ₁₃₃₀ / I ₁₅₈₀ = 1.1, carbon film content rate 5%, carbon film average coverage rate 90%, carbon film average thickness 110nm, carbon film true density = 1.6g/cm ³ , carbon film adsorption isotherm type: type II, carbon film specific surface area = 180m ² /g, carbon film Compression resistivity (1.0 g/cm ³ ) = 8.00 × 10 ^-3 Ω ‧ cm, carbon film compression density (50 MPa) = 1.1 g / cm ³ , TOF-SIMS C _y H _z y = 2, 3, 4 z =2y-3, 2y-1, 2y+1 Int(C ₄ H ₉ /C ₃ H ₅ )=0.8 FEC:EC:DMC=1:2:7 LIPF ₆ 1.2mol/kg, positive LiCoO ₂ , negative electrode bonding Agent PAA, active substance ratio: 100% of lanthanide active substance particles

As can be seen from Table 4, when the range of 5.0≧A/B≧0.01, 6.0≧(A+B)/C≧0.02 is satisfied (Examples 1-3, 4-3, 4-4), the maintenance rate, the first time Efficiency is a good feature. When the a-Si component is increased, the initial efficiency is lowered, but the maintenance rate is increased. This is because the equilibrium system is maintained in the range of 5.0 ≧A/B ≧ 0.01. In addition, when the ratio (A+B)/C of the Si component to the SiO ₂ component is 6 or less, the expansion accompanying the insertion of Li can be suppressed to be small, and the maintenance ratio is improved. Further, when (A+B)/C is 0.02 or more, the conductivity is improved, and the maintenance ratio and the initial efficiency are improved. In the case where only 5.0≧A/B≧0.01 is satisfied (Examples 4-1 and 4-6), it is maintained as compared with the case where both of the above ranges of A/B and (A+B)/C are satisfied. The rate is somewhat reduced. In the case where only 6.0≧(A+B)/C≧0.02 is satisfied (Examples 2-2 and 2-5), both of the above ranges of A/B and (A+B)/C are satisfied. In the case of the situation, the maintenance rate is somewhat reduced.

(Example 5-1 to Example 5-5)

The production of the secondary battery was carried out in the same manner as in Example 1-3, except that the crystallinity of the ruthenium compound was changed. Non-atmospheric ring Controlled by heat treatment under the environment. The crystallite size was calculated to be 1.542 in Example 5-1, but the peak was substantially not obtained as a result of fitting using the analytical software. Therefore, the ruthenium compound of Example 5-1 can be said to be substantially amorphous.

The cycle characteristics and initial charge and discharge characteristics of the secondary batteries of Examples 5-1 to 5-5 were investigated, and the results shown in Table 5 were obtained.

[Table 5] SiO _x (x = 0.9), NMR: A / B = 0.6 (A + B) / C = 0.32, D ₅₀ = 5.1 μm, carbon film Raman I ₁₃₃₀ / I ₁₅₈₀ = 1.1, carbon film true Density = 1.6g/cm ³ , carbon film adsorption isotherm type: type II, carbon film specific surface area = 180m ² /g, carbon film compression resistivity (1.0g/cm ³ ) = 8.00 × 10 ^-3 Ω‧cm The carbon material has a compression density (50 MPa) = 1.1 g/cm ³ , a carbon film content rate of 5%, a carbon film average coverage rate of 90%, a carbon film average thickness of 110 nm, and TOF-SIMS C _y H _z y = 2, 3, 4 z=2y-3, 2y-1, 2y+1 Int(C ₄ H ₉ /C ₃ H ₅ )=0.8, FEC:EC:DMC=1:2:7 LIPF ₆ 1.2mol/kg, positive LiCoO ₂ , negative electrode binder PAA, active material ratio: lanthanum active material particles 100%

It can be seen from Table 5 that when the crystallinity of the ruthenium compound is changed, The capacity retention rate and initial efficiency change should be based on their crystallinity. In particular, a high retention ratio due to a low crystallinity material having a crystallite size of 7.5 nm or less due to the Si (111) plane is possible. In particular, the best maintenance ratio can be obtained in the amorphous region. In addition, the initial efficiency is somewhat lowered as the crystallinity is lowered, but an initial efficiency is obtained which is not a problem.

(Examples 6-1 to 6-3)

In addition to changing the state of the surface of the carbon film of the silicon compound, the carbon film changes in Raman spectroscopic analysis of 1330cm ^-1 and 1580cm ^-1 of the scattering peak intensity ratio than I ₁₃₃₀ / I _1580, carried out in the same manner as in Example 1-3 Manufacturing of secondary batteries. Further, the intensity ratio of the scattering peak I ₁₃₃₀ /I ₁₅₈₀ can be changed by changing the temperature at the time of CVD and the gas pressure.

When the cycle characteristics and the initial charge and discharge characteristics of the secondary batteries of Examples 6-1 to 6-3 were investigated, the results shown in Table 6 were obtained.

[Table 6] SiO _x (x = 0.9), NMR: A / B = 0.6 (A + B) / C = 0.32, D ₅₀ = 5.1 μm, Si (111) half value width θ = 1.85 ° Microcrystals 4.62 nm

Carbon film true density = 1.6g/cm ³ , carbon film adsorption isotherm type: type II, carbon film specific surface area = 180m ² /g, carbon film content rate 5%, carbon film average coverage rate 90%, carbon film average thickness 110nm, carbon film compression resistivity (1.0g/cm ³ ) = 8.00 × 10 ^-3 Ω ‧ cm, carbon film compression density (50MPa) = 1.1g / cm ³ , TOF-SIMS C _y H _z y = 2 3, 4 z=2y-3, 2y-1, 2y+1 Int(C ₄ H ₉ /C ₃ H ₅ )=0.8, FEC:EC:DMC=1:2:7, LIPF ₆ 1.2 mol/kg, Positive LiCoO ₂ , negative electrode binder PAA, active material ratio: 100% lanthanide active material particles

As shown in Table 6, when the intensity ratio of the scattering peak in the Raman spectrum is less than 2.0, I ₁₃₃₀ /I ₁₅₈₀ , since the carbon component having a disordered bonding pattern from I ₁₃₃₀ on the surface is small, electron conductivity is high, and the retention ratio is high. The first time the efficiency is improved. In addition, when I ₁₃₃₀ /I _{1580 is} more than 0.7, the carbon component such as graphite from I ₁₅₈₀ is small on the surface, and the ionic conductivity and the carbon film are improved in the followability to the expansion of the Li compound of the ruthenium compound, and the capacity is maintained. The rate is increased.

(Example 7-1 to Example 7-5, Comparative Example 7-1)

A secondary battery was produced in the same manner as in Example 1-3, except that the state of the carbon film on the surface of the ruthenium compound was adjusted. That is, in Examples 7-1 to 7-5, the detection intensity D and C ₃ of the C _y H _z fragment detected by the TOF-SIMS from the carbon film and the C ₄ H ₉ in the TOF-SIMS were changed. The intensity ratio of the detection intensity E of H ₅ is D/E. At this time, the gas type, the CVD temperature, and the post-CVD treatment temperature at the time of using CVD for the ruthenium compound were adjusted. Further, in Comparative Example 7-1, the coating of the carbon film was not performed.

When the cycle characteristics and the initial charge and discharge characteristics of the secondary batteries of Examples 7-1 to 7-5 and Comparative Example 7-1 were investigated, the knots shown in Table 7 were obtained. fruit.

[Table 7] SiO _x (x = 0.9), NMR: A / B = 0.6 (A + B) / C = 0.32, D ₅₀ = 5.1 μm, Si (111) half value width θ = 1.85 ° Microcrystals 4.62 nm

Carbon film Raman I ₁₃₃₀ /I ₁₅₈₀ =1.1, carbon film true density = 1.6g/cm ³ , carbon film adsorption isotherm type: type II, carbon film specific surface area = 180m ² /g, carbon film compression resistivity (1.0 g/cm ³ hr) = 8.00 × 10 ^-3 Ω ‧ cm, carbon film compression density (50 MPa) = 1.1 g / cm ³ , carbon film content rate 5%, carbon film average coverage rate 90%, carbon film average thickness 110 nm , FEC: EC: DMC=1: 2:7 LIPF ₆ 1.2mol/kg, positive LiCoO ₂ , negative electrode binder PAA, active material ratio: lanthanide active material particles 100%

When as shown in Table 7, fragments detected based compound _z C _y H and satisfies 2.5 ≧ D / E ≧ 0.3 relationship, the battery characteristics are improved. Further, in Comparative Example 7-1, when the carbon-free film was not formed, the conductivity of the negative electrode was deteriorated, and the maintenance ratio and the initial efficiency were deteriorated. Further, satisfying the condition of 6 ≧ y ≧ 2, 2y + 2 ≧ z ≧ range of C-2y-2 when _{y z} fragment of compound H, the battery characteristics are improved. In particular, when the y value is small, that is, when only a fragment of the _{y Hz} compound of y=2, 3, or 4 is detected, the battery characteristics are further improved.

(Examples 8-1 to 8-5)

A secondary battery was produced in the same manner as in Example 1-3, except that the median diameter of the ruthenium compound was adjusted. The adjustment of the median diameter is carried out by changing the pulverization time and the classification conditions in the production step of the ruthenium compound. When the cycle characteristics and the initial charge and discharge characteristics of the secondary batteries of Examples 8-1 to 8-5 were investigated, the results shown in Table 8 were obtained.

[Table 8] SiO _x (x = 0.9), NMR: A / B = 0.6 (A + B) / C = 0.32, Si (111) half value width θ = 1.85 ° Microcrystals 4.62 nm

Carbon film Raman I ₁₃₃₀ /I ₁₅₈₀ =1.1, carbon film true density = 1.6g / cm ³ , carbon film adsorption isotherm: type II, carbon film specific surface area = 180m ² / g, carbon film content rate 5%, The carbon film has an average coverage of 90%, the carbon film has an average thickness of 110 nm, and the carbon film has a compressive resistivity (1.0 g/cm ³ ) = 8.00 × 10 ^-3 Ω ‧ cm, and the carbon film has a compression density (50 MPa) = 1.1 g / cm ³ , TOF-SIMS C _y H _z y=2,3,4 z=2y-3, 2y-1, 2y+1 Int(C ₄ H ₉ /C ₃ H ₅ )=0.8, FEC:EC:DMC=1 :2:7 LIPF ₆ 1.2mol/kg, positive LiCoO ₂ , negative electrode binder PAA, active material ratio: lanthanide active material particles 100%

As is clear from Table 8, when the median diameter of the ruthenium compound was changed, the maintenance ratio and the initial efficiency were changed accordingly. As shown in Examples 8-2 to 8-4, when the median diameter of the ruthenium compound particles is from 0.5 μm to 20 μm, the capacity retention ratio is changed to be high. In particular, when the median diameter is 0.5 μm or more and 12 μm or less, the improvement of the maintenance ratio can be seen.

(Examples 9-1 to 9-2)

A secondary battery was fabricated in the same manner as in Example 1-3 except that Li was doped in the ruthenium compound and Li was contained in at least a part of the lanthanum-based active material particles. Li doping was carried out in Example 9-1 using a thermal hybrid method in an electrochemical method in Example 9-2.

When the cycle characteristics and the initial charge and discharge characteristics of the secondary batteries of Examples 9-1 to 9-2 were investigated, the results shown in Table 9 were obtained.

[Table 9] SiO _x (x = 0.9), NMR: A / B = 0.6 (A + B) / C = 0.32, D ₅₀ = 5.1 μm, Si (111) half value width θ = 1.85 ° Microcrystals 4.62 nm

Carbon film Raman I ₁₃₃₀ /I ₁₅₈₀ =1.1, carbon film true density = 1.6g / cm ³ , carbon film adsorption isotherm type: type II, carbon film specific surface area = 180m ² /g, carbon film compression resistivity (1.0 g/cm ³ hr) = 8.00 × 10 ^-3 Ω ‧ cm, carbon film compression density (50 MPa) = 1.1 g / cm ³ , carbon film content rate 5%, carbon film average coverage rate 90%, carbon film average thickness 110 nm , TOF-SIMS C _y H _z y=2,3,4 z=2y-3, 2y-1, 2y+1 Int(C ₄ H ₉ /C ₃ H ₅ )=0.8, FEC:EC:DMC=1 :2:7 LIPF ₆ 1.2mol/kg, positive LiCoO ₂ , active material ratio: 100% of lanthanide active material particles

As is clear from Table 9, the maintenance ratio was improved by including Li in the lanthanide-based active material particles. Further, as in Example 9-2, when Li was doped into the lanthanum-based active material particles by an electrochemical reforming method, the initial efficiency was improved. In addition, the initial efficiency of the negative electrode in the case of the nonaqueous electrolyte secondary battery is increased, and the balance between the positive electrode and the negative electrode during the cycle test is suppressed, and the maintenance ratio is improved.

(Example 10-1 to Example 10-6)

In the examples 10-1 to 10-6, the secondary battery was produced in the same manner as in the example 1-3. However, as the negative electrode active material, a carbon-based active material (artificial graphite and natural graphite was further added). The mass ratio of the 1:1 mass ratio is changed, and the content ratio of the ruthenium compound and the carbon-based active material in the negative electrode (the ratio of the ruthenium compound (SiO material) to the entire active material) is changed, and the binder is also changed depending on the ratio. In Examples 10-1 to 10-3, as bonding For the agent, a styrene butadiene rubber (described as SBR in Table 10) and CMC were used. In Examples 10-4 to 10-6, polyimide (described as PI in Table 10) was used as the binder.

(Comparative Example 10-1)

Except that the negative electrode active material of the present invention is not contained, only the carbon-based active materials used in Examples 10-1 to 10-6 are used as the negative electrode active material, and the lithium nickel cobalt aluminum composite oxide is used as the positive electrode material. A secondary battery was produced in the same manner as in Example 1-3 except for use.

The cycle characteristics and initial charge and discharge characteristics of the secondary batteries of Examples 10-1 to 10-6 and Comparative Example 10-1 were investigated. Further, the power capacity density (mAh/cm ³ ) of the secondary batteries of Examples 10-1 to 10-6 and Comparative Example 10-1 was measured, and the power capacity density of the secondary battery of Comparative Example 10-1 was used as a reference. The relative power capacity density at that time is calculated in each case. The results of these are shown in Table 10.

[Table 10] SiO _x (x = 0.9), NMR: A / B = 0.6 (A + B) / C = 0.32, D ₅₀ = 5.1 μm, Si (111) half value width θ = 1.85 ° Microcrystals 4.62 nm

Carbon film Raman I ₁₃₃₀ /I ₁₅₈₀ =1.1, carbon film true density = 1.6g/cm ³ , carbon film adsorption isotherm type: type II, carbon film specific surface area = 180m ² /g, carbon film compression resistivity (1.0 g/cm ³ hr) = 8.00 × 10 ^-3 Ω ‧ cm, carbon film compression density (50 MPa) = 1.1 g / cm ³ , carbon film content rate 5%, carbon film average coverage rate 90%, carbon film average thickness 110 nm , TOF-SIMS C _y H _z y=2, 3, 4 z=2y-3, 2y-1, 2y+1 Int(C ₄ H ₉ /C ₃ H ₅ )=0.8 FEC:EC:DMC=1: 2:7 LIPF ₆ 1.2mol/kg, positive LiCoO ₂

As is clear from Table 10, when the ratio of the lanthanum active material particles is increased, the capacity of the negative electrode is increased, but the initial efficiency and the maintenance ratio are lowered. Further, the relative power capacity density shown in Table 10 is as described above, and the ratio of the lanthanum active material particles is 0 and combined with the NCA (lithium nickel cobalt aluminum composite oxide) positive electrode material, and the discharge cutoff voltage of the battery is set to The power capacity density at 2.5 V (Comparative Example 10-1) was used as a reference. When the ratio of the lanthanum active material particles is reduced, the initial efficiency and the maintenance ratio are improved, but the power capacity density is small. In particular, in Comparative Example 10-1, when only a carbon-based active material was used as the negative electrode active material, a lithium ion secondary battery having a high power capacity density could not be obtained. In particular, when the ratio of the lanthanum-based active material particles is 5% by mass or more, the power capacity density is sufficiently improved.

(Examples 11-1 to 11-8)

In addition to changing the average particle diameter G of the carbon-based active material in the negative electrode active material layer (the median diameter D _{50 of the} carbon active material particles) and the average particle diameter F of the lanthanoid active material (the median diameter D of the lanthanum-based active material particles) ₅₀ ) The secondary battery was produced in the same manner as in Example 10-2 except that the ratio G/F was changed.

When the cycle characteristics and the initial charge and discharge characteristics of the secondary batteries of Examples 11-1 to 11-8 were investigated, the results shown in Table 11 were obtained.

[Table 11] SiO _x (x = 0.9), NMR: A / B = 0.6 (A + B) / C = 0.32, D ₅₀ = 5.1 μm, Si (111) half value width θ = 1.85 ° Microcrystals 4.62 nm

Carbon film Raman I ₁₃₃₀ /I ₁₅₈₀ =1.1, carbon film true density = 1.6g/cm ³ , carbon film adsorption isotherm type: type II, carbon film specific surface area = 180m ² /g, carbon film compression resistivity (1.0 g/cm ³ hr) = 8.00 × 10 ^-3 Ω ‧ cm, carbon film compression density (50 MPa) = 1.1 g / cm ³ , carbon film content rate 5%, carbon film average coverage rate 90%, carbon film average thickness 110 nm _{, TOF-SIMS C y H z} y = 2,3,4 z = 2y-3,2y-1,2y + 1 Int (C 4 H 9 / C 3 H 5) = 0.8 FEC: EC: DMC = 1: 2:7 LIPF ₆ 1.2mol/kg, positive LiCoO ₂ , active material ratio: 5% active lanthanide particles

As is clear from Table 11, the carbon-based active material particles in the negative electrode active material layer are preferably equal to or larger than the lanthanum-based active material particles. Small, that is, G/F≧0.5. When the swelling and contracting cerium compound is equal to or smaller than the carbon-based negative electrode material, the destruction of the composite material layer can be prevented. When the carbon-based negative electrode material is increased with respect to the ruthenium compound, the negative electrode bulk density and initial efficiency at the time of charging are improved, and the battery energy density is improved. In particular, by satisfying the range of 25 ≧G/F ≧ 0.5, the initial efficiency and the maintenance rate are further improved.

(Example 12-1 to Example 12-4)

The secondary battery was produced in the same manner as in Example 10-2 except that the type of the carbon-based active material in the negative electrode was changed.

When the cycle characteristics and the initial charge and discharge characteristics of the secondary batteries of Examples 12-1 to 12-4 were investigated, the results shown in Table 12 were obtained.

[Table 12] SiO _x (x = 0.9), NMR: A / B = 0.6 (A + B) / C = 0.32, D ₅₀ = 5.1 μm, Si (111) half value width θ = 1.85 ° Microcrystals 4.62 nm

Carbon film Raman I ₁₃₃₀ /I ₁₅₈₀ =1.1, carbon film true density = 1.6g/cm ³ , carbon film adsorption isotherm type: type II, carbon film specific surface area = 180m ² /g, carbon film compression resistivity (1.0 g/cm ³ hr) = 8.00 × 10 ^-3 Ω ‧ cm, carbon film compression density (50 MPa) = 1.1 g / cm ³ , carbon film content rate 5%, carbon film average coverage rate 90%, carbon film average thickness 110 nm , TOF-SIMS C _y H _z y=2, 3, 4 z=2y-3, 2y-1, 2y+1 Int(C ₄ H ₉ /C ₃ H ₅ )=0.8 FEC:EC:DMC=1: 2:7 LIPF ₆ 1.2mol/kg, positive LiCoO ₂ , negative electrode binder CMC/SBR, active material ratio: 5% active material particles

As is clear from Table 12, it is preferable that the carbon-based active material particles in the negative electrode active material layer contain a graphite-based material such as artificial graphite or natural graphite. Since the graphite-based carbon material has a high initial efficiency and a high retention rate, when the negative electrode is mixed with the lanthanum-based active material particles, the battery characteristics are relatively improved.

(Example 13-1)

A laminate film type secondary battery as shown in Fig. 3 was produced by the following method.

Initially, the positive electrode was made. The mixed positive electrode active material is LiNi _0.7 Co _0.25 Al _0.05 O 95% by mass of the lithium nickel cobalt composite oxide, 2.5% by mass of the positive electrode conductive auxiliary agent, and 2.5% by mass of the positive electrode binder (polyvinylidene fluoride: PVDF) to form a positive electrode mixture. . Next, the positive electrode mixture was dispersed in an organic solvent (N-methyl-2-pyrrolidone, NMP) to form a paste-like slurry. Further, the slurry was applied to both sides of the positive electrode current collector by a coating device having a die, and dried by a hot air drying device. At this time, the positive electrode current collecting system used a thickness of 15 μm. Finally, compression molding is carried out by rolling.

Next, a negative electrode was produced. First, a negative electrode active material was produced as follows. The raw material in which the metal ruthenium and the ruthenium dioxide were mixed was introduced into a reaction furnace, and the gasified material was deposited on the adsorption plate in an environment of a vacuum of 10 Pa, and after sufficiently cooled, the deposit was taken out and pulverized by a ball mill. The x value of SiO _x of the ruthenium compound particles thus obtained was 1.0. Next, the particle size of the ruthenium compound particles is adjusted by classification. Then, thermal decomposition CVD is performed to coat the carbon coating on the surface of the cerium compound particles. At this time, in the thermal decomposition CVD, a rotary kiln type reaction furnace was used, the carbon source was methane gas, the temperature in the furnace was set to 1000 ° C, the pressure was set at 1 atm, and the CVD time was set to 6 hours.

Next, lithium is inserted into the ruthenium compound particles by a redox method to be modified. First, the ruthenium compound particles are immersed in a solution (solution A ₁ ) of biphenyl in which a lithium sheet and a linear polyphenylene compound are dissolved in tetrahydrofuran (hereinafter also referred to as THF). The solution A ₁ was prepared by dissolving biphenyl in a concentration of 1 mol/L in a THF solvent, and then adding a 10% by mass lithium ion mass to the mixed liquid of THF and biphenyl. Further, the temperature of the solution when the cerium compound particles were impregnated was 20 ° C, and the immersion time was 10 hours. Then, the ruthenium compound particles were collected by filtration. Lithium is inserted into the ruthenium compound particles by the above treatment.

Subsequently, the ruthenium compound particles after lithium insertion were immersed in a solution (solution B) in which naphthalene was dissolved in THF. Solution B was prepared by dissolving naphthalene at a concentration of 2 mol/L in a THF solvent. Further, the temperature of the solution when the cerium compound particles were impregnated was 20 ° C, and the immersion time was 20 hours. Then, the ruthenium compound particles were collected by filtration.

Next, the ruthenium compound particles after the contact with the solution B were immersed in a solution (solution C) in which p-benzoquinone was dissolved at a concentration of 1 mol/L in THF. The immersion time was 2 hours. Then, the ruthenium compound particles were collected by filtration. By the above treatment, Li ₂ SiO ₃ and Li ₄ SiO _{4 are} formed inside the ruthenium compound particles.

Subsequently, the cerium compound particles are washed, and the cerium compound particles after the washing treatment are dried under reduced pressure. In this way, the negative electrode active material particles were obtained.

Next, in the same manner as in Example 1-1, the specific surface area of the multi-point BET method of the separated carbon film and the compression resistivity when compressed to a density of 1.0 g/cm ³ were measured.

As a result, the specific surface area of the multi-point BET method of the separated carbon film was 180 m ² /g, and the compression resistivity at a density of 1.0 g/cm ³ was 8.0 × 10 ^-3 Ω ‧ cm.

Next, the negative electrode active material particles and the carbon-based active material were blended at a mass ratio of 1:9 to prepare a mixed negative electrode active material. Here, as the carbon-based active material, natural graphite and artificial graphite coated with the asphalt layer are mixed at a mass ratio of 5:5. Further, the median diameter of the carbon-based active material was 20 μm.

Next, the prepared mixed negative electrode active material, conductive auxiliary 1 (carbon nanotube, CNT), conductive auxiliary 2 (carbon fine particles having a median diameter of about 50 nm), and styrene butadiene rubber (styrene butyl) The olefin copolymer, hereinafter referred to as SBR) and carboxymethyl cellulose (hereinafter referred to as CMC) are mixed at a dry mass ratio of 92.5:1:1:2.5:3, and then diluted with pure water to form a negative electrode mixture slurry. Furthermore, the above SBR, CMC negative electrode binder (negative Extreme adhesive).

Further, as the negative electrode current collector, an electrolytic copper foil having a thickness of 15 μm was used. Carbon and sulfur were contained in the electrolytic copper foil at a concentration of 70 ppm by mass. Finally, the negative electrode mixture slurry was applied onto the negative electrode current collector, and dried at 100 ° C for 1 hour in a vacuum atmosphere. The amount of deposition (also referred to as an area density) of the negative electrode active material layer per unit area on one side of the negative electrode after drying was 5 mg/cm ² .

Next, after mixing a solvent (4-fluoro-1,3-dioxolan-2-one (FEC)), ethyl carbonate (EC), and dimethyl carbonate (DMC), an electrolyte salt (hexafluorocarbon) is obtained. Lithium phosphate: LiPF ₆ ) was dissolved to prepare an electrolyte. At this time, the composition of the solvent was made to be FEC:EC:DMC=10:20:70 by volume ratio, and the content of the electrolyte salt was 1.2 mol/kg with respect to the solvent.

Next, the secondary battery was assembled as follows. Initially, at one end of the positive electrode current collector, an aluminum wire is ultrasonically welded, and a nickel wire is welded to one end of the negative electrode current collector. Further, the positive electrode, the separator, the negative electrode, and the separator were laminated in this order to obtain a wound electrode body wound in the longitudinal direction. The end portion of the winding was fixed with PET protective tape. As the separator, a laminate film (thickness: 12 μm) obtained by sandwiching a film containing porous polypropylene as a main component on a film containing porous polyethylene as a main component was used. Next, after sandwiching the electrode body between the exterior members, the outer peripheral edge portions are thermally fused to each other, and the electrode body is housed inside. The exterior member is an aluminum laminate film synthesized by laminating a nylon film, an aluminum foil, and a polypropylene film. Continuing, the adjusted electrolyte is injected from the opening, and after being impregnated in a vacuum environment, it is thermally fused and closed.

The cycle characteristics and the initial charge and discharge characteristics of the secondary battery produced as described above were evaluated in the same manner as in Example 1-1.

(Example 13-2 to Example 13-5)

The same procedure as in Example 13-1 was carried out except that the IUPAC classification of the adsorption-desorption isotherm of the detached carbon film and the compression density of the detached carbon film (pressure at 50 MPa) were changed as shown in Table 13. The manufacture of the battery, evaluation of cycle characteristics and initial charge and discharge characteristics. The IUPAC classification of the adsorption and desorption isotherms of the detached carbon film, and the compression density (50 MPa pressure) of the detached carbon film can be adjusted by adjusting the CVD temperature, time, and bismuth compound during CVD. Controlled by the agitation of the particles.

(Comparative Example 13-1 to Comparative Example 13-4)

Except that the specific surface area of the detached carbon film was changed as shown in Table 13, the compression resistivity when the detached carbon film was compressed to a density of 1.0 g/cm ³ , and the average true density of the carbon film in the surface of the ruthenium compound, The secondary battery was produced in the same manner as in Example 13-1 except that the IUPAC classification of the adsorption and desorption isotherms of the carbon film was carried out, and the cycle characteristics and the initial charge and discharge characteristics were evaluated. These parameters can also be controlled by adjusting the CVD temperature, time, and agitation of the cerium compound particles during CVD.

At this time, the negative electrode active material particles of Examples 13-1 to 13-5 and Comparative Examples 13-1 to 13-4 had the following properties. The median diameter of the negative electrode active material particles was 4 μm. Further, the yttrium compound is obtained by X-ray diffraction, and the half value width (2θ) of the diffraction peak due to the Si (111) crystal plane is 2.257°, the crystallite size resulting from the Si(111) crystal plane was 3.77 nm.

Among the negative electrode active material particles, the maximum peak intensity value H obtained from the ²⁹ Si-MAS-NMR spectrum as the chemical shift value of -75 to -94 ppm and the maximum peak intensity value H of the lithium niobate region, and the chemical shift The relationship between the peak intensity values I of the meteorite regions given at values of -95 to -150 ppm is H>I.

Further, a coin battery type test cell of 2032 size was produced from the negative electrode and the counter lithium produced as described above, and the discharge behavior was evaluated. More specifically, charging was first terminated at a time when the current density reached 0.05 mA/cm ² by performing constant current constant voltage charging on the pole Li until 0 V. Then, constant current discharge was performed until 1.2 V. The current density at this time was 0.2 mA/cm ² . This charge and discharge was repeated 30 times, and the data obtained from each charge and discharge was plotted as a plot of the rate of change of the capacity (dQ/dV) on the vertical axis and the voltage (V) on the horizontal axis, confirming that V is in the range of 0.4 to 0.55 (V). Can you get a peak? As a result, in the examples and the comparative examples, the peaks were obtained during charge and discharge within 30 times, and the peaks were obtained during all charge and discharge from the charge and discharge of the peaks first exhibited to the 30th charge and discharge. .

Table 13 shows the evaluation results of Examples 13-1 to 13-5 and Comparative Examples 13-1 to 13-4.

[Table 13] SiO _x x = 1 D ₅₀ = 4 μm, containing lithium niobate, having a dQ/dV peak, graphite (natural graphite: artificial graphite = 5:5) D ₅₀ = 20 μm, Si (111) half value width θ =2.257° Microcrystalline 3.77 nm, H>1, active material ratio: 10% by mass of lanthanum active material particles, positive electrode NCA, negative electrode current collector: carbon 70 ppm, sulfur 70 ppm

As can be seen from Table 13, in Examples 13-1 to 13-5 in which the specific surface area of the separated carbon film was 5 m ² /g or more and 1000 m ² /g or less, the specific surface area was outside the range. In Comparative Example 13-3 and Comparative Example 13-4, more excellent battery characteristics were obtained. Further, in Examples 13-1 to 13-5 in which the compression resistivity at a density of the carbon film of 1.0 g/cm ³ was 1.0 × 10 ^-3 Ω ‧ cm or more and 1.0 Ω ‧ cm or less, Comparative Example 13-3 and Comparative Example 13-4 having a compression resistivity outside the range were able to obtain more excellent battery characteristics.

(Example 14-1)

The relationship between the maximum peak intensity value H of the negative electrode active material particles and the peak intensity value H derived from the tantalate region is such that H<I is the same as in Example 13-1. A secondary battery was fabricated under the same conditions, and cycle characteristics and initial efficiency were evaluated. At this time, by reducing the amount of insertion of lithium at the time of reforming, the amount of Li ₂ SiO ₃ is reduced, and the intensity H of the peak derived from Li ₂ SiO ₃ is reduced.

[Table 14] SiO _x x = 1 D ₅₀ = 4 μm, containing lithium niobate, having a dQ/dV peak, an average true density of 1.1 g/cm ³ , an isolated carbon film: a specific surface area of 180 m ² /g, and a compression resistance Rate 8.0×10 ^-3 Ω‧cm, compression density 1.1g/cm ³ , adsorption and desorption isotherm classification type II, graphite (natural graphite: artificial graphite = 5:5) D ₅₀ = 20μm, Si (111) half Value width θ=2.257° Microcrystalline 3.77 nm, active material ratio: 10% by mass of lanthanum active material particles, positive electrode NCA, negative electrode current collector: carbon 70 ppm, sulfur 70 ppm

As can be seen from Table 14, when the relationship between the peak intensities is H>I, the battery characteristics are improved.

(Example 15-1)

Except for the V-dQ/dV curve obtained by using 30 times of charge and discharge in the above test battery, any negative electrode active material in which the charge and discharge are in the range of 0.40 V to 0.55 V cannot be obtained, and Example 13-1 A secondary battery was fabricated under the same conditions, and cycle characteristics and initial efficiency were evaluated.

[Table 15] SiO _x x = 1 D ₅₀ = 4 μm, containing lithium niobate, an average true density of 1.1 g/cm ³ , an isolated carbon film: a specific surface area of 180 m ² /g, and a compression resistivity of 8.0 × 10 ^-3 Ω‧cm, compressed density 1.1g / cm ^3, adsorption-desorption isotherms of type II classification, graphite (natural graphite: artificial graphite _{= 5: 5) D 50 =} 20μm, Si (111) half-width θ = 2.257 ° Microcrystalline 3.77 nm, active material ratio: 10% by mass of lanthanum active material particles, positive electrode NCA, negative electrode current collector: carbon 70 ppm, sulfur 70 ppm

Since the shape of the discharge curve rises more sharply, it is necessary to exhibit the same discharge behavior as ruthenium (Si) in the ruthenium compound (SiO _x ). Since the peak was not exhibited in the above range in the 30th charge and discharge, the ruthenium compound became a relatively flat discharge curve, and when the secondary battery was formed, the initial efficiency was somewhat lowered. As long as the peaks are exhibited in charge and discharge within 30 times, a stable whole is formed, and the capacity retention rate and the initial efficiency are improved.

(Example 16-1)

A secondary battery was fabricated under the same conditions as in Example 13-1 except that a copper foil containing no carbon or sulfur was used as the negative electrode current collector, and the cycle characteristics and the initial efficiency were evaluated.

[Table 16] SiO _x x = 1 D ₅₀ = 4 μm, containing lithium niobate, having a dQ/dV peak, an average true density of 1.1 g/cm ³ , an isolated carbon film: a specific surface area of 180 m ² /g, and a compression resistance Rate 8.0×10 ^-3 Ω‧cm, compression density 1.1g/cm ³ , adsorption and desorption isotherm classification type II, graphite (natural graphite: artificial graphite = 5:5) D ₅₀ = 20μm, Si (111) half Value width θ=2.257° Microcrystalline 3.77 nm, active material ratio: 10% by mass of lanthanum active material particles, positive electrode NCA,

When carbon and sulfur of 100 ppm by mass or less are contained in the current collector of the negative electrode, the strength of the current collector is improved. Therefore, when the ruthenium-based negative electrode active material having a large expansion or contraction at the time of charge and discharge of the secondary battery is used, deformation and strain of the current collector accompanying the secondary battery can be suppressed, and as in the embodiment 13-1, the battery characteristics, particularly the cycle characteristics, are improved. .

(Comparative Example 17-1)

The secondary battery was produced in the same manner as in Example 13-1 except that lithium was not inserted into the ruthenium compound particles, and the cycle characteristics and the initial charge and discharge characteristics were evaluated.

[Table 17] SiO _x x = 1 D ₅₀ = 4 μm, having a dQ/dV peak, an average true density of 1.1 g/cm ³ , an isolated carbon film: a specific surface area of 180 m ² /g, and a compression resistivity of 8.0 × 10 ^{- 3} Ω‧cm, compression density 1.1g/cm ³ , adsorption and desorption isotherm classification type II, graphite (natural graphite: artificial graphite = 5:5) D ₅₀ = 20μm, Si (111) half value width θ = 2.257 ° Microcrystalline 3.77nm, active material ratio: 10% by mass of lanthanum active material particles, positive electrode NCA, negative electrode current collector: carbon 70ppm, sulfur 70ppm

As is clear from Table 17, Example 13-1, which was modified by inserting lithium into the ruthenium-active material particles, was improved in both the initial efficiency and the maintenance ratio as compared with Example 17-1 in which the modification was not carried out.

Furthermore, the present invention is not limited to the above embodiments. The above-described embodiment is exemplified, and has substantially the same configuration as the technical idea described in the patent application scope of the present invention, and achieves the same operational effects. Anybody is included in the technical scope of the present invention.

10‧‧‧negative

11‧‧‧Negative current collector

12‧‧‧Negative active material layer

Claims (26)

A negative electrode active material for a nonaqueous electrolyte secondary battery, which comprises a negative electrode active material particle, and the negative electrode active material particle contains a negative electrode active material for a nonaqueous electrolyte secondary battery of a cerium compound (SiO _x : 0.5 ≦ x ≦ 1.6), The negative electrode active material particle has a carbon film on at least a part of the surface, and the carbon film is separated from the carbon film by the negative electrode active material particle, and the measured multi-point BET method has a specific surface area of 5 m ² /g. more than 1000m ² / g or less, and the carbon-based coating film from the negative electrode active material coating the carbon particles isolated, the measured resistivity based compression when compressed to 1.0g / cm ^3, a density of 1.0 × 10 ^-3 Ω‧ Above 1.0 cm ‧ cm or less. The negative electrode active material for a nonaqueous electrolyte secondary battery according to claim 1, wherein the carbon film has a true density of 1.2 g/cm ³ or more and 1.9 g/cm ³ or less. The negative electrode active material for a non-aqueous electrolyte secondary battery according to claim 1 or 2, wherein the carbon film is separated from the negative electrode active material particle by the carbon film, and the mass per unit area is 0.15 g/cm ² . After the separated carbon film was placed in the measurement container, the compression density at the time of compression at 50 MPa was 1.0 g/cm ³ or more and 1.8 g/cm ³ or less. The negative electrode active material for a non-aqueous electrolyte secondary battery according to claim 1 or 2, wherein the content of the carbon film is 0.1% by mass or more and 25% by mass or less based on the negative electrode active material particles. The negative electrode active material for a nonaqueous electrolyte secondary battery according to claim 1 or 2, wherein the carbon film is contained in an adsorption/desorption isotherm of nitrogen gas measured by separating the negative electrode active material particles from the carbon film. The aforementioned adsorption and desorption isotherms are characterized by type II or type III of the IUPAC classification. The negative electrode active material for a nonaqueous electrolyte secondary battery according to claim 1 or 2, wherein the ruthenium compound is removed from the negative electrode active material particles by reacting the negative electrode active material particles with a solution containing hydrofluoric acid and nitric acid. Thereby, the separation of the aforementioned carbon film is performed. The non-aqueous electrolyte secondary battery negative electrode active material of the requested item 1 or 2, wherein the carbon-based coating film in a Raman spectrum obtained by Raman spectroscopic analysis of at 1330cm ^-1 and 1580cm ^-1 scattering peaks, Peter other scattering peak intensity satisfy _{0.7 <I 1330 / I 1580 <} 2.0 ratio I ₁₃₃₀ / I _1580. The negative electrode active material for a non-aqueous electrolyte secondary battery according to claim 1 or 2, wherein the carbon film is a fragment of a _Cy H _z- based compound detected by TOF-SIMS as a fragment of the _Cy H _z- based compound. At least a portion of the range that satisfies 6≧y≧2, 2y+2≧z≧2y-2 is detected. The negative electrode active material for a nonaqueous electrolyte secondary battery according to claim 8, wherein the fragment of the _Cy H _z compound detected by the carbon film is a detection intensity D and C ₃ of C ₄ H ₉ in TOF-SIMS. The detection intensity E of H ₅ satisfies the relationship of 2.5 ≧D/E ≧ 0.3. The negative electrode active material for a nonaqueous electrolyte secondary battery according to claim 1 or 2, wherein the carbon film has an average thickness of 5 nm or more and 5000 nm or less. The anode of the nonaqueous electrolyte secondary battery of claim 1 or 2 is alive The substance, wherein the carbon film has an average coverage of 30% or more. The negative electrode active material for a nonaqueous electrolyte secondary battery according to claim 1 or 2, wherein the carbon film is obtained by thermally decomposing a carbon-containing compound. The negative electrode active material for a nonaqueous electrolyte secondary battery according to claim 1 or 2, wherein in the ruthenium compound, the chemical shift value obtained from the ²⁹ Si-MAS-NMR spectrum is -20 to -74 ppm. The peak area A of the germanium region and the peak area B of the crystalline germanium region and the lithium niobate region given at -75 to -94 ppm and the peak area C of the meteorite region given at -95 to -150 ppm satisfy the formula ( 1); Formula (1): 5.0 ≧ A / B ≧ 0.01, 6.0 ≧ (A + B) / C ≧ 0.02. The negative electrode active material for a nonaqueous electrolyte secondary battery according to claim 1 or 2, wherein the negative electrode active material particle is a half value width (2θ) of a diffraction peak due to a Si (111) crystal plane obtained by X-ray diffraction. It is 1.2° or more, and the crystallite size due to the crystal face is 7.5 nm or less. The negative electrode active material for a nonaqueous electrolyte secondary battery according to claim 1 or 2, wherein a median diameter of the negative electrode active material particles is 0.5 μm or more and 20 μm or less. The negative electrode active material for a nonaqueous electrolyte secondary battery according to claim 1 or 2, wherein Li is contained in at least a part of the negative electrode active material particles. The negative electrode active material for a non-aqueous electrolyte secondary battery according to claim 16, wherein at least one of Li ₂ SiO ₃ and Li ₄ SiO ₄ is contained in at least a part of the negative electrode active material particles. The negative electrode active material for a nonaqueous electrolyte secondary battery according to claim 1 or 2, wherein the negative electrode active material particles are obtained from a ²⁹ Si-MAS-NMR spectrum as a chemical shift value of -75 to -94 ppm. The maximum peak intensity value H of the crystalline germanium region and the lithium niobate region and the peak intensity value I of the vermiculite region given as the chemical shift value of -95 to -150 ppm satisfy the relationship of H>I. The negative electrode active material for a nonaqueous electrolyte secondary battery according to claim 1 or 2, wherein the negative electrode and the counter electrode lithium are formed from a mixture comprising the negative electrode active material for a nonaqueous electrolyte secondary battery and a carbon active material. In the test battery, charging is performed by inserting lithium into the negative electrode active material for a nonaqueous electrolyte secondary battery, and lithium is removed from the negative electrode active material for the nonaqueous electrolyte secondary battery. The charge and discharge of the discharge of the current is 30 times, and the differential value dQ/dV after the discharge potential Q in each charge and discharge is differentiated by the potential V of the negative electrode based on the counter lithium is shown. In the case of the relationship with the potential V, the potential V of the negative electrode has a peak in the range of 0.40 V to 0.55 V during the discharge of the Xth time (1≦X≦30). The negative electrode active material for a nonaqueous electrolyte secondary battery according to claim 1 or 2, which further contains carbon-based active material particles. The negative electrode active material for a non-aqueous electrolyte secondary battery according to claim 20, wherein the mass ratio of the negative electrode active material particles is 5% by mass or more based on the total mass of the negative electrode active material particles and the carbon-based active material particles. The negative electrode active material for a non-aqueous electrolyte secondary battery according to claim 21, wherein the average particle diameter F of the negative electrode active material particles is 25 ≧G/F ≧ 0.5 with respect to the average particle diameter G of the carbon-based active material particles. Relationship. The negative electrode active material for a nonaqueous electrolyte secondary battery according to claim 22, wherein the carbon active material particles are graphite materials. A negative electrode active material layer containing a negative electrode active material for a nonaqueous electrolyte secondary battery according to any one of claims 1 to 23, and a negative electrode current collector, the foregoing The negative electrode active material layer is formed on the negative electrode current collector, and the negative electrode current collector contains carbon and sulfur, and the content thereof is 100 ppm by mass or less. A nonaqueous electrolyte secondary battery comprising the negative electrode active material for a nonaqueous electrolyte secondary battery according to any one of claims 1 to 23. A method for producing a negative electrode material for a nonaqueous electrolyte secondary battery, which is a method for producing a negative electrode material for a nonaqueous electrolyte secondary battery comprising negative electrode active material particles, characterized in that it is produced by using SiO _x (0.5 ≦ x ≦ 1.6) a step of expressing particles of the ruthenium compound, a step of coating at least a part of the surface of the ruthenium compound particles with a carbon film, and a step of selecting particles of the ruthenium compound coated with the carbon film, the carbon film being coated with The particles of the ruthenium compound of the carbon film are separated from the carbon film, and the specific surface area of the multi-point BET method measured is 5 m ² /g or more and 1000 m ² /g or less, and the particles are separated from the ruthenium compound coated with the carbon film. In the carbon film, the measured compressive resistivity is 1.0 × 10 ^-3 Ω ‧ cm or more and 1.0 Ω ‧ cm or less when compressed to a density of 1.0 g/cm ³ ; and the selected carbon film is coated with the carbon film The particles of the compound are used as the negative electrode active material particles to produce a negative electrode material for a nonaqueous electrolyte secondary battery.