JP2018195586A - Negative electrode material for lithium ion secondary battery, negative electrode for lithium ion secondary battery, and lithium ion secondary battery - Google Patents

Abstract

To provide a negative electrode material for a lithium ion secondary battery capable of constituting the lithium ion secondary battery excellent in initial charging capacity, charging and discharging efficiency and cycle characteristics.SOLUTION: A negative electrode material for a lithium ion secondary battery includes: a silicon oxide particle 20; an element 10 of carbon existing in a part or all of a surface of the silicon oxide particle 20; and one type of conductive particle 14 selected from a group consisting of carbon black and granular graphite adhering to the surface of the silicon oxide particle 20 in which the element 10 of carbon exists on the surface.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a negative electrode material for a lithium ion secondary battery, a negative electrode for a lithium ion secondary battery, and a lithium ion secondary battery.

At present, graphite is mainly used as a negative electrode material for lithium ion secondary batteries, and it is known that graphite has a theoretical capacity limit of 372 mAh / g in discharge capacity. In recent years, with the improvement in performance of mobile devices such as mobile phones, notebook computers and tablet terminals, the demand for higher capacity of lithium ion secondary batteries has become stronger, and the further increase in capacity of lithium ion secondary batteries has increased. There is a need for achievable negative electrode materials.
Therefore, a negative electrode using an element having a high theoretical capacity and capable of occluding and releasing lithium ions (hereinafter also referred to as “specific element”. The element containing the specific element is also referred to as “specific element body”). Material development is active.

  As the specific element, silicon, tin, lead, aluminum and the like are well known. Among them, silicon oxide, which is one of the specific element bodies, has advantages such as higher capacity, lower cost and better workability than negative electrode materials made of other specific elements. Research is particularly active.

  On the other hand, these specific element bodies are known to undergo large volume expansion when alloyed by charging. Such volume expansion makes the specific element bodies themselves finer, and further, the structure of the negative electrode material using these elements is broken and the conductivity is cut. Therefore, it has been a problem that the capacity is remarkably lowered with the passage of cycles.

For example, in Patent Document 1, a diffraction peak attributed to Si (111) is observed in X-ray diffraction, and a silicon crystal obtained by the Scherrer method based on the half-value width of the diffraction line is disclosed in Patent Document 1. The surface of a particle having a structure in which silicon crystallites are dispersed in a silicon compound and having a size of 1 to 500 nm is coated with carbon. A silicon composite is disclosed.
According to the technique of Patent Document 1, silicon crystals or fine particles are dispersed in an inert and strong substance, such as silicon dioxide, and carbon for imparting conductivity to at least a part of the surface is fused. As a result, it is said that the structure is stable with respect to the volume change caused by insertion and extraction of lithium as well as the surface conductivity, and as a result, the long-term stability and the initial efficiency are improved.

Moreover, in patent document 2, it is the electroconductive powder which coat | covered the surface of the material which can occlude and discharge | release lithium ion with a graphite film | membrane, a graphite coating amount is 3 to 40 weight%, and a BET specific surface area is 2-30 m < ² > / g. a is, graphite coating, according to the Raman spectrum, the Raman shift is the negative electrode material for a nonaqueous electrolyte secondary battery characterized by having a spectrum of graphite structure-specific are disclosed in the vicinity of 1330 cm ^-1 and 1580 cm ^-1 ing.
According to the technique of Patent Document 2, by controlling the physical properties of a graphite film covering the surface of a material capable of occluding and releasing lithium ions within a specific range, a lithium ion secondary that can reach a characteristic level required by the market. It is said that the negative electrode of a battery is obtained.

In Patent Document 3, a negative electrode material used in the negative electrode for a secondary battery with a nonaqueous electrolyte, negative electrode material, the carbon film on the surface of the silicon oxide particles represented by the general formula SiO _x There is disclosed a negative electrode material for a non-aqueous electrolyte secondary battery, characterized in that it is coated and the carbon film is subjected to a thermal plasma treatment.
According to the technique of Patent Document 3, the negative electrode material effective for non-aqueous electrolyte secondary battery negative electrode having excellent cycle characteristics is obtained by solving the expansion of the electrode, which is a defect of silicon oxide, and the expansion of the battery due to gas generation. It is supposed to be done.

Japanese Patent No. 3952180 Japanese Patent No. 4171897 JP 2011-90869 A

However, when silicon oxide, which is one of the specific element bodies, is used as the negative electrode material, the initial charge / discharge efficiency is low, and the battery capacity of the positive electrode is excessive when applied to an actual battery. Even in this technology, the feature of silicon oxide having a high capacity could not be fully utilized in an actual lithium ion secondary battery. In addition, as a negative electrode material to be applied to lithium ion secondary batteries suitable for higher performance of mobile devices and the like in the future, not only can a large amount of lithium ions be stored (high charge capacity), but also stored lithium It is necessary to be able to release more ions. Therefore, as the negative electrode material that contributes to further performance improvement of the lithium ion secondary battery, it is important to improve both the initial discharge capacity and the initial charge / discharge efficiency.
In addition to this, as a negative electrode material that contributes to further improving the performance of lithium ion secondary batteries, it is important to suppress not only the initial characteristics, but also the reduction in capacity due to repeated charge and discharge, and improvement in cycle characteristics is also required. It is done.
The present invention has been made in view of the above requirements, and has a negative electrode material for a lithium ion secondary battery, a negative electrode for a lithium ion secondary battery, and a lithium ion secondary battery that are excellent in initial discharge capacity, initial charge / discharge efficiency, and cycle characteristics. It is an object to provide a secondary battery.

  Specific means for solving the above problems are as follows.

(1) silicon oxide particles, a simple substance of carbon existing on a part or all of the surface of the silicon oxide particles, granular graphite adhering to the surface of the silicon oxide particles where the simple substance of carbon is present on the surface, and A negative electrode material for a lithium ion secondary battery, comprising a kind of conductive particles selected from the group consisting of carbon black.
(2) The negative electrode material for a lithium ion secondary battery according to (1), wherein the conductive particles include at least the granular graphite.
(3) The negative electrode material for a lithium ion secondary battery according to (2), wherein the granular graphite is flat graphite.
(4) The negative electrode material for a lithium ion secondary battery according to any one of (1) to (3), wherein the content of the conductive particles is 1.0% by mass to 10.0% by mass.
(5) The negative electrode material for a lithium ion secondary battery according to any one of (1) to (4), wherein the content of the simple substance of carbon is 0.5 mass% to 10.0 mass%.
(6) An X-ray diffraction spectrum having CuKα rays as a radiation source has a diffraction peak attributed to Si (111), and the silicon crystallite size calculated from the diffraction peak is 2.0 nm to 8 The negative electrode material for a lithium ion secondary battery according to any one of (1) to (5), which is 0.0 nm.
(7) A current collector, and a negative electrode material layer including the negative electrode material for a lithium ion secondary battery according to any one of (1) to (6) provided on the current collector. Negative electrode for lithium ion secondary battery.
(8) A lithium ion secondary battery comprising a positive electrode, the negative electrode for a lithium ion secondary battery according to (7), and an electrolyte.

  According to the present invention, it is possible to provide a negative electrode material for a lithium ion secondary battery, a negative electrode for a lithium ion secondary battery, and a lithium ion secondary battery that are excellent in initial discharge capacity, initial charge / discharge efficiency, and cycle characteristics. .

It is a schematic sectional drawing which shows an example of a structure of the negative electrode material of this invention. It is a schematic sectional drawing which shows another example of a structure of the negative electrode material of this invention. It is a schematic sectional drawing which shows another example of a structure of the negative electrode material of this invention. It is sectional drawing to which some negative electrode materials of FIGS. 1-3 were expanded. (A) illustrates one aspect of the state of the carbon simple substance 10 in the negative electrode material, and (B) describes another aspect of the state of the carbon simple substance 10 in the negative electrode material.

In the present specification, a numerical range indicated using “to” indicates a range including the numerical values described before and after “to” as the minimum value and the maximum value, respectively.
Further, in the present specification, the amount of each component in the composition is the amount of each of the plurality of substances present in the composition unless there is a specific indication when there are a plurality of substances corresponding to each component in the composition. It means the total amount.

<Anode material for lithium ion secondary battery>
The negative electrode material for a lithium ion secondary battery of the present invention (hereinafter sometimes abbreviated as “negative electrode material”) is composed of silicon oxide particles and a simple substance of carbon existing on part or all of the surface of the silicon oxide particles. And granular graphite adhering to the surface of silicon oxide particles having carbon alone (hereinafter, silicon oxide particles having carbon alone may be abbreviated as “SiO-C particles”). And a kind of conductive particles selected from the group consisting of carbon black.

  The negative electrode material of the present invention can alleviate the expansion and contraction of the silicon oxide particles due to the insertion and extraction of lithium ions by the presence of a simple substance of carbon on the surface of the silicon oxide particles. Therefore, the initial discharge capacity and the initial charge / discharge efficiency are excellent. In addition, when conductive graphite or carbon black further adheres to the surface of the SiO—C particles, a conductive protrusion structure is imparted to the surface of the SiO—C particles. For this reason, even if silicon oxide particles expand and contract, conduction between adjacent negative electrode materials is facilitated. Further, the resistance value of the entire negative electrode material can be reduced. As a result, the initial discharge capacity and the initial charge / discharge efficiency are further improved, the capacity decrease due to repeated charge / discharge can be suppressed, and the cycle characteristics are excellent.

(Silicon oxide particles)
The negative electrode material of the present invention contains silicon oxide particles. The silicon oxide constituting the silicon oxide particles may be an oxide containing silicon element, and examples thereof include silicon monoxide (also referred to as silicon oxide), silicon dioxide, silicon suboxide and the like. These may be used individually by 1 type and may be used in combination of multiple types.
Among silicon oxides, silicon oxide and silicon dioxide are generally represented as silicon monoxide (SiO) and silicon dioxide (SiO ₂ ), respectively, but the surface state (eg, the presence of an oxide film) or Depending on the state of formation of the compound, the measured value (or converted value) of the contained element may be represented by the composition formula SiOx (x is 0 <x ≦ 2). In this case, the silicon oxide of the present invention is also used. Note that the value of x can be calculated, for example, by quantifying oxygen contained in silicon oxide by an inert gas melting-non-dispersive infrared absorption method. In addition, when a disproportionation reaction of silicon oxide (2SiO → Si + SiO ₂ ) is involved in the production process of the negative electrode material of the present invention, the chemical reaction includes silicon and silicon dioxide (in some cases, silicon oxide). In this case, the silicon oxide according to the present invention is used.
Silicon oxide can be obtained, for example, by a known sublimation method in which a gas of silicon monoxide generated by heating a mixture of silicon dioxide and metal silicon is cooled and precipitated. Moreover, it can obtain from a market as a silicon oxide, silicon monoxide, etc.

  The silicon oxide particles preferably have a structure in which silicon crystallites are dispersed in silicon oxide. In the case where silicon crystallites are dispersed in silicon oxide particles, when X-ray powder diffraction (XRD) measurement using CuKα rays as a radiation source is performed, Si (111) is around 2θ = 28.4 °. A diffraction peak attributed to is observed. When silicon crystallites are present in the silicon oxide particles, it is easy to obtain a high initial discharge capacity and a good initial charge / discharge efficiency.

The size of silicon crystallites is preferably 8.0 nm or less, and more preferably 6.0 nm or less. When the crystallite size is 8.0 nm or less, the silicon crystallites are less likely to be localized in the silicon oxide particles, so that lithium ions are easily diffused in the silicon oxide particles, and the charge capacity is good. Is easy to obtain.
Further, the size of the silicon crystallite is preferably 2.0 nm or more, and more preferably 3.0 nm or more. When the crystallite size is 2.0 nm or more, the reaction between lithium ions and silicon oxide is controlled, and good charge / discharge efficiency is easily obtained.

  The size of the silicon crystallite is the half-value width of the diffraction peak around 2θ = 28.4 ° attributed to Si (111) obtained by powder X-ray diffraction analysis using a CuKα ray having a wavelength of 0.154056 nm as a radiation source. Therefore, it can be obtained using Scherrer's equation.

  A structure in which silicon crystallites are dispersed in silicon oxide particles can be prepared by, for example, disproportionating the silicon oxide particles by heat treatment in an inert atmosphere at a temperature range of 700 ° C. to 1300 ° C. it can. Moreover, it can produce by adjusting the heating temperature in the heat processing for providing the simple substance of below-mentioned carbon to a silicon oxide particle. In addition, there exists a tendency for the magnitude | size of the silicon crystallite to become large, so that the heating temperature at the time of heat processing becomes high, and heating time becomes long.

  The silicon oxide particles can be produced by pulverizing and classifying when a bulk silicon oxide having a size of several cm square is prepared. Specifically, it is preferable to firstly perform primary pulverization and classification to a size that can be charged into a fine pulverizer, and then secondary pulverize this with a fine pulverizer. The average particle diameter of the silicon oxide particles obtained by secondary pulverization is preferably 0.1 μm to 20 μm, preferably 0.5 μm to 10 μm, in accordance with the final desired negative electrode material size. More preferred. The average particle diameter is the volume cumulative 50% particle diameter (D50%) of the particle size distribution. Hereinafter, the same applies to the description of the average particle diameter. For measuring the average particle diameter, a known method such as a laser diffraction particle size distribution analyzer can be employed.

(Carbon simple substance)
The negative electrode material of the present invention contains a simple substance of carbon existing on a part or all of the surface of silicon oxide particles. Here, the simple substance of carbon indicates amorphous carbon that is present on a part or all of the surface of the silicon oxide particles and does not have a specific shape. Specifically, for example, the simple substance of carbon indicates amorphous carbon existing in a film shape on a part or all of the surface of the silicon oxide particles.

  The content of the simple carbon is preferably 0.5% by mass to 10.0% by mass in the total amount of the silicon oxide particles and the simple carbon. By setting it as such a structure, it exists in the tendency for the initial stage discharge capacity and initial stage charge-and-discharge efficiency to improve more. The carbon content is preferably 1.0% by mass to 9.0% by mass, more preferably 2.0% by mass to 8.0% by mass, and 3.0% by mass to 7.0% by mass. Particularly preferred.

The simple substance of carbon is preferably low crystalline. Low crystallinity means that the R value obtained by the method shown below is 0.5 or more.
Single carbon in a profile obtained by laser Raman spectroscopy of the excitation wavelength 532 nm, the intensity of the peak appearing the intensity of the peak appearing in the vicinity of 1360 cm ^-1 Id, in the vicinity of 1580 cm ^-1 and Ig, the both peaks When the intensity ratio Id / Ig (also expressed as D / G) is an R value, the R value is preferably 0.5 to 1.5, more preferably 0.7 to 1.3, More preferably, it is 0.8-1.2. When the R value is 0.5 to 1.5, the particle surface is coated with low crystalline carbon in which carbon crystallites are randomly oriented, so that the reactivity with the electrolytic solution can be reduced, and the cycle characteristics tend to be improved. There is.

Here, the peak appearing in the vicinity of 1360 cm ⁻¹ is usually a peak identified as corresponding to a single amorphous structure of carbon, for example, a peak observed at 1300 cm ^{−1 to} 1400 cm ^−1. . Also, the peak appearing near 1580 cm ^-1, generally a peak identified as corresponding to the graphite crystal structure, for ^example, refers to peaks observed at 1530cm ^-1 ~1630cm -1.
Incidentally, R value Raman spectrum measuring apparatus (e.g., NSR-1000 type, manufactured by JASCO Corporation) was used, the ^{1050cm -1 ~1750cm} -1 as a baseline for the measurement range ^{(830cm -1 ~1940cm} -1) Can be sought.

  The method for imparting simple carbon to the surface of the silicon oxide particles is not particularly limited, and examples thereof include a wet mixing method, a dry mixing method, and a chemical vapor deposition method. The wet mixing method or the dry mixing method is preferable from the viewpoint that the reaction system can be uniformly controlled and the shape of the negative electrode material can be maintained.

  In the case of the wet mixing method, for example, silicon oxide particles and a solution in which a carbon source is dissolved in a solvent are mixed, and the carbon source solution is adhered to the surface of the silicon oxide particles, and a solvent is used as necessary. Then, the carbon source can be carbonized by heat treatment in an inert atmosphere to give a simple substance of carbon. In addition, when a carbon source does not melt | dissolve in a solvent, it can also be set as the dispersion liquid which disperse | distributed the carbon source in the dispersion medium.

In the case of the dry mixing method, for example, silicon oxide particles and a carbon source are mixed in a solid state to form a mixture, and the carbon source is carbonized by heat-treating the mixture in an inert atmosphere, thereby oxidizing silicon. The simple substance of carbon can be provided to the surface of the product particles. In addition, when mixing a silicon oxide particle and a carbon source, you may perform the process (for example, mechanochemical process) which adds mechanical energy.
In the case of the chemical vapor deposition method, a known method can be applied. For example, the silicon oxide particles are heat-treated in an atmosphere containing a gas obtained by vaporizing a carbon source, thereby imparting simple carbon to the surface of the silicon oxide particles. can do.

  In the case of applying carbon simple substance to the surface of silicon oxide particles by the above method, the carbon source is not particularly limited as long as it is a compound that can leave carbon simple substance by heat treatment. Specifically, polymer compounds such as phenol resin, styrene resin, polyvinyl alcohol, polyvinyl chloride, polyvinyl acetate, polybutyral; ethylene heavy end pitch, coal-based pitch, petroleum pitch, coal tar pitch, asphalt decomposition pitch, Examples thereof include PVC pitches produced by thermally decomposing polyvinyl chloride and the like, naphthalene pitches such as naphthalene pitch produced by polymerizing in the presence of a super strong acid, and polysaccharides such as starch and cellulose. These carbon sources may be used alone or in combination of two or more.

  When carbon is applied to the surface of silicon oxide particles by chemical vapor deposition, the carbon source can be gaseous or easily gasified among aliphatic hydrocarbons, aromatic hydrocarbons, alicyclic hydrocarbons, etc. Preference is given to using possible compounds. Specific examples include methane, ethane, propane, toluene, benzene, xylene, styrene, naphthalene, cresol, anthracene, and derivatives thereof. These carbon sources may be used alone or in combination of two or more.

  The heat treatment temperature for carbonizing the carbon source is not particularly limited as long as the carbon source is carbonized, and is preferably 700 ° C. or higher, more preferably 800 ° C. or higher, and 900 ° C. or higher. More preferably it is. Further, from the viewpoint of making the simple substance of carbon low crystalline and from the viewpoint of generating silicon crystallites in a desired size, it is preferably 1300 ° C. or less, more preferably 1200 ° C. or less, and more preferably 1100 ° C. More preferably, it is as follows.

  The heat treatment time is appropriately selected depending on the type of carbon source to be used and the amount of the carbon source used, and for example, 1 hour to 10 hours is preferable, and 2 hours to 7 hours is more preferable.

  Note that the heat treatment is preferably performed in an inert atmosphere such as nitrogen or argon. The heat treatment apparatus is not particularly limited as long as a reaction apparatus having a heating mechanism is used, and examples thereof include a heating apparatus capable of processing by a continuous method, a batch method, or the like. Specifically, a fluidized bed reaction furnace, a rotary furnace, a vertical moving bed reaction furnace, a tunnel furnace, a batch furnace or the like can be appropriately selected according to the purpose.

  The heat-treated product obtained by the heat treatment is preferably crushed because individual particles may be aggregated. Moreover, when adjustment to a desired average particle diameter is required, you may further grind | pulverize.

(Conductive particles)
In the negative electrode material of the present invention, a kind of conductive particles selected from the group consisting of granular graphite and carbon black are attached to the surface of the SiO—C particles. It is sufficient that at least one of granular graphite and carbon black adheres to the surface of the SiO—C particles, and it is preferable that the granular graphite adheres from the viewpoint of improving cycle characteristics.

  Examples of granular graphite include particles such as artificial graphite, natural graphite, and MC (mesophase carbon).

The granular graphite preferably has higher crystallinity than the simple substance of carbon existing on the surface of the silicon oxide particles, from the viewpoint that both the battery capacity and the charge / discharge efficiency are improved. Specifically, the spherical graphite preferably has an average interplanar spacing (d ₀₀₂ ) value obtained by measurement based on the Gakushin method of 0.335 nm to 0.347 nm, more preferably 0.335 nm to 0.345 nm. 0.335 nm to 0.340 nm is more preferable, and 0.335 nm to 0.337 nm is particularly preferable. When the average surface spacing of the spherical graphite is 0.347 nm or less, the crystallinity of the granular graphite is high, and both the battery capacity and the charge / discharge efficiency tend to be improved. On the other hand, since the theoretical value of the graphite crystal is 0.335 nm, when the average interplanar spacing of the spherical graphite is close to this value, both the battery capacity and the charge / discharge efficiency tend to be improved.

  The granular graphite may be either flat graphite or spherical graphite, and is preferably flat graphite from the viewpoint of improving cycle characteristics.

  Flat graphite is a particle of graphite having a major axis and a minor axis and having a non-spherical shape, such as a scaly shape, a scaly shape, or a partial lump shape.

  The aspect ratio of the flat graphite is not particularly limited, but it is preferably 3 or more, more preferably 5 or more from the viewpoint of facilitating conductivity between particles and improving cycle characteristics.

  The aspect ratio of flat graphite is such that the length in the major axis direction of flat graphite is A, and the length in the minor axis direction of flat graphite (length in the thickness direction of flat graphite) is B. It is expressed as A / B. The aspect ratio of the flat graphite was obtained by enlarging the flat graphite with a microscope, arbitrarily selecting 10 flat graphites, measuring each A / B, and taking the arithmetic average value of the measured values. Is.

  Examples of carbon black include acetylene black, ketjen black, thermal black, and furnace black. Among these, acetylene black is preferable from the viewpoint of conductivity.

  The content of the conductive particles (amount based on the SiO—C particles) is preferably 1.0% by mass to 10.0% by mass with respect to the SiO—C particles in terms of improving cycle characteristics, and is 2.0% by mass -9.0 mass% is more preferable, 3.0 mass%-8.0 mass% is still more preferable.

  The content rate of electroconductive particle can be calculated | required by the high frequency baking-infrared analysis method also including the simple substance of carbon. In the high-frequency firing-infrared analysis method, for example, a carbon-sulfur simultaneous analyzer (CSLS600, LECO Japan LLC) can be used.

  The method for attaching the conductive particles to the surface of the SiO—C particles (for example, composite) is not particularly limited, and examples thereof include a wet method and a dry method.

Examples of the wet method include the following methods. First, a particle dispersion liquid in which conductive particles are dispersed in a dispersion medium is prepared using a known dispersing machine such as a stirring type homogenizer, a bead mill, or a ball mill. Next, after adding SiO-C particles to the obtained particle dispersion, stirring is performed using a known dispersing machine such as a stirring homogenizer, a bead mill, or a ball mill. Then, the dispersion medium is removed from the particle dispersion in which the conductive particles and the SiO—C particles are dispersed using a dryer or the like. Thereby, electroconductive particle can be made to adhere to the surface of a SiO-C particle (for example, composite).
Here, an organic solvent such as water or alcohol can be used as the dispersion medium. Moreover, you may add a dispersing agent to the particle dispersion liquid from the point which improves the dispersibility of electroconductive particle and implement | achieves the uniform adhesion | attachment of the electroconductive particle to the surface of a SiO-C particle | grain. The dispersant can be appropriately selected depending on the dispersion medium to be used. As the dispersant, for example, carboxymethyl cellulose is preferable because it is excellent in dispersion stability if it is aqueous.

  The dry method includes, for example, a method in which conductive particles are added at the same time when carbon simple substance is added to silicon oxide particles. Specifically, for example, when the silicon oxide particles and the carbon source are mixed, the conductive particles are also mixed together and subjected to a process of applying mechanical energy (for example, a mechanochemical process). Thereby, electroconductive particle can be made to adhere to the surface of a SiO-C particle (for example, composite).

  Through the above steps, a negative electrode material in which conductive particles adhere to the surface of the SiO—C particles is obtained. In addition, after removing a dispersion medium from particle | grain dispersion liquid, you may classify the obtained negative electrode material using a sieve etc. as needed.

Hereinafter, an example of the negative electrode material of the present invention will be described with reference to the drawings.
1 to 3 are schematic cross-sectional views showing examples of the configuration of the negative electrode material of the present invention.
In FIG. 1, the carbon simple substance 10 covers the entire surface of the silicon oxide particles 20. In FIG. 2, the carbon simple substance 10 covers the entire surface of the silicon oxide particle 20, but does not cover it uniformly. In FIG. 3, the carbon simple substance 10 is partially present on the surface of the silicon oxide particles 20, and the surface of the silicon oxide particles 20 is partially exposed. 1 to 3, the conductive particles 14 are attached to the surface of the silicon oxide particles 20 (SiO—C particles) on which the carbon simple substance 10 exists in this state.
1 to 3, the shape of the silicon oxide particles 20 is schematically represented as a sphere (a circle as a cross-sectional shape), but the spherical shape, the block shape, the scale shape, and the cross-sectional shape are polygonal. It may be any shape (cornered shape) or the like. Moreover, in FIGS. 1-3, although the shape of the electroconductive particle 14 is represented by flat shape, it is not necessarily restricted to this.

  FIG. 4 is an enlarged cross-sectional view of a part of the negative electrode material of FIGS. 1 to 3, and FIG. 4A illustrates one aspect of the shape of the simple carbon 10 in the negative electrode material, and FIG. Then, the other aspect of the shape of the carbon simple substance 10 in a negative electrode material is demonstrated. In the case of FIGS. 1 to 3, even if the carbon simple substance 10 is entirely composed of carbon as shown in FIG. 4 (A), the carbon simple substance 10 is composed of particles 12 as shown in FIG. 4 (B). It may be configured. Although FIG. 4B shows the carbon 12 with the contour shape of the particles 12 remaining, the particles 12 may be bonded to each other. When the particles 12 are bonded to each other, the carbon simple substance 10 may be entirely composed of carbon, but voids may be included in a part of the carbon simple substance 10. Thus, a void may be included in a part of the carbon simple substance 10.

  The volume-based average particle diameter D50% of the negative electrode material of the present invention is preferably 0.1 μm to 20 μm, and more preferably 0.5 μm to 10 μm. When the average particle size is 20 μm or less, the distribution of the negative electrode material in the negative electrode is made uniform, and further, the expansion and contraction at the time of charge and discharge are made uniform, so that the deterioration of cycle characteristics can be suppressed. Further, when the average particle diameter is 0.1 μm or more, the negative electrode density tends to increase and the capacity tends to increase.

The specific surface area of the negative electrode material of the present invention is preferably 0.1m ² / g~15m ² / g, more preferably ^{0.5m 2 / g~10m 2 / g,} 1.0m 2 / more preferably g~7.0m is ² / g, it is more particularly preferred is 1.0m ² /g~3.0m ² / g.
When the specific surface area is 15 m ² / g or less, an increase in the first irreversible capacity of the obtained lithium ion secondary battery can be suppressed. Furthermore, an increase in the amount of binder used can be suppressed when producing the negative electrode. When the specific surface area is 0.1 m ² / g or more, the contact area between the negative electrode material and the electrolytic solution increases, and the charge / discharge efficiency increases. For the measurement of the specific surface area, a known method such as the BET method (nitrogen gas adsorption method) can be employed.

  In the negative electrode material of the present invention, the content of the conductive particles is 1.0% by mass to 10.0% by mass, and the content of the simple carbon is 0.5% by mass to 10.0% by mass. The crystallite size of silicon is preferably 2.0 nm to 8.0 nm, the content of conductive particles is 2.0 mass% to 9.0 mass%, and the content of carbon alone is It is 1.0 mass%-9.0 mass%, and it is more preferable that the magnitude | size of the crystallite of silicon is 3.0 nm-6.0 nm.

The negative electrode material of the present invention may be used in combination with a carbon-based negative electrode material conventionally known as an active material for a negative electrode of a lithium ion secondary battery, if necessary. Depending on the type of carbon-based negative electrode material used in combination, an improvement in charge and discharge efficiency, an improvement in cycle characteristics, an electrode expansion suppression effect, and the like can be obtained.
Conventionally known carbon-based negative electrode materials include natural graphite such as flaky natural graphite, spherical natural graphite obtained by spheroidizing flaky natural graphite, artificial graphite, amorphous carbon, and the like. Further, these carbon-based negative electrode materials may further have carbon on a part or all of the surface thereof. One or more of these carbon-based negative electrode materials may be used by mixing with the negative electrode material of the present invention.

  When the negative electrode material of the present invention is used in combination with a carbon-based negative electrode material, the ratio (A: B) of the negative electrode material (A) of the present invention to the carbon-based negative electrode material (B) is appropriately adjusted according to the purpose. Is possible. For example, from the viewpoint of the effect of suppressing the expansion of the electrode, the mass is preferably 0.1: 99.9 to 20:80, and more preferably 0.5: 99.5 to 15:85. 1: 99-10: 90 is more preferable.

<Anode for lithium ion secondary battery>
The negative electrode for a lithium ion secondary battery of the present invention (hereinafter sometimes abbreviated as “negative electrode”) includes a current collector and the negative electrode material for a lithium ion secondary battery of the present invention provided on the current collector. A negative electrode material layer. For example, the negative electrode for a lithium ion secondary battery of the present invention includes a negative electrode material for a lithium ion secondary battery of the present invention, an organic binder, a solvent such as a solvent or water, and, if necessary, a thickener, a conductive aid, By preparing a coating liquid in which a known carbon-based negative electrode material or the like is mixed and applying this coating liquid to a current collector, the solvent or water is dried, and pressure forming is performed to form a negative electrode material layer. can get. Generally, it is kneaded with an organic binder, a solvent or the like, and formed into a sheet shape, a pellet shape or the like.

  It does not specifically limit as an organic binder, Styrene-butadiene copolymer; methyl (meth) acrylate, ethyl (meth) acrylate, butyl (meth) acrylate, (meth) acrylonitrile, hydroxyethyl (meth) acrylate, etc. (Meth) acrylic copolymer obtained by copolymerizing ethylenically unsaturated carboxylic acid ester and ethylenically unsaturated carboxylic acid such as acrylic acid, methacrylic acid, itaconic acid, fumaric acid, maleic acid; And polymer compounds such as vinylidene chloride, polyethylene oxide, polyepichlorohydrin, polyphosphazene, polyacrylonitrile, polyimide, and polyamideimide. “(Meth) acrylate” means “acrylate” and “methacrylate” corresponding thereto. The same applies to other similar expressions such as “(meth) acrylic copolymer”.

  These organic binders include those dispersed or dissolved in water or those dissolved in an organic solvent such as N-methyl-2-pyrrolidone (NMP) depending on the respective physical properties. Among these, an organic binder whose main skeleton is polyacrylonitrile, polyimide or polyamideimide is preferable because of its excellent adhesion, and the heat treatment temperature during the preparation of the negative electrode is low as described later, and the flexibility of the electrode is excellent. Therefore, an organic binder whose main skeleton is polyacrylonitrile is more preferable. Examples of the organic binder having polyacrylonitrile as a main skeleton include, for example, a product obtained by adding acrylic acid for imparting adhesiveness and a linear ether group for imparting flexibility to a polyacrylonitrile skeleton (LSR7 (trade name), Hitachi Kasei Co., Ltd.) can be used.

The content ratio of the organic binder in the negative electrode material layer of the negative electrode material for a lithium ion secondary battery is preferably 0.1% by mass to 20% by mass, and preferably 0.2% by mass to 20% by mass. Is more preferable, and it is still more preferable that it is 0.3 mass%-15 mass%.
When the content ratio of the organic binder is 0.1% by mass or more, the adhesion is good, and the destruction of the negative electrode due to expansion and contraction during charge / discharge is suppressed. On the other hand, it can suppress that electrode resistance becomes large because it is 20 mass% or less.

Furthermore, as a thickener for adjusting the viscosity, carboxymethylcellulose, methylcellulose, hydroxymethylcellulose, ethylcellulose, polyvinyl alcohol, polyacrylic acid (salt), oxidized starch, phosphorylated starch, casein, and the like are the organic binders described above. May be used together.
A solvent may be used as necessary when mixing the organic binder. The solvent is not particularly limited, and N-methylpyrrolidone, dimethylacetamide, dimethylformamide, γ-butyrolactone and the like are used.

  In addition, you may add a conductive support agent to a coating liquid. Examples of the conductive assistant include carbon black, acetylene black, conductive oxide, and conductive nitride. These conductive assistants may be used alone or in combination of two or more. It is preferable that the content rate of a conductive support agent is 0.1 mass%-20 mass% in a negative electrode material layer (100 mass%).

  The material of the current collector is not particularly limited, and examples thereof include aluminum, copper, nickel, titanium, stainless steel, porous metal (foamed metal), and carbon paper. The shape of the current collector is not particularly limited, and examples thereof include a foil shape, a perforated foil shape, and a mesh shape.

The method for applying the coating liquid to the current collector is not particularly limited, and is a metal mask printing method, electrostatic coating method, dip coating method, spray coating method, roll coating method, doctor blade method, gravure coating method, screen printing. Law. After the application, it is preferable to perform a pressure treatment with a flat plate press, a calender roll or the like, if necessary.
Moreover, the integration of the coating liquid and the current collector formed into a sheet shape, a pellet shape, or the like can be performed by, for example, integration by a roll, integration by a press, or integration by a combination thereof.

The negative electrode material layer formed on the current collector or the negative electrode material layer integrated with the current collector is preferably heat-treated according to the organic binder used. For example, when using an organic binder having polyacrylonitrile as the main skeleton, heat treatment is preferably performed at 100 ° C. to 180 ° C., and when using an organic binder having polyimide or polyamideimide as the main skeleton, 150 is used. It is preferable to heat-treat at a temperature of from 450C.
This heat treatment increases the strength by removing the solvent and curing the organic binder, thereby improving the adhesion between the negative electrode material and the adhesion between the negative electrode material and the current collector. Note that these heat treatments are preferably performed in an inert atmosphere such as helium, argon, nitrogen, or a vacuum atmosphere in order to prevent oxidation of the current collector during the treatment.

In addition, the negative electrode is preferably pressed (pressurized) before the heat treatment. The electrode density can be adjusted by applying pressure treatment. It The negative electrode for a lithium ion secondary battery of the present invention, it is preferable that the electrode density of ^{1.4g / cm 3 ~1.9g / cm 3} , a 1.5g / cm ³ ~1.85g / cm 3 it is more ^preferable, and further preferably from ^{1.6g / cm 3 ~1.8g / cm 3} . As the electrode density is higher, the volume capacity of the negative electrode tends to be improved, and the adhesion between the negative electrode material and the adhesion between the negative electrode material and the current collector tend to be improved.

<Lithium ion secondary battery>
The lithium ion secondary battery of the present invention includes a positive electrode, a negative electrode of the present invention, and an electrolyte.
The negative electrode of the present invention can be formed into a lithium ion secondary battery by, for example, disposing a positive electrode with a separator interposed therebetween and injecting an electrolytic solution containing an electrolyte.

  The positive electrode can be obtained by forming a positive electrode layer on the current collector surface in the same manner as the negative electrode of the present invention. As the current collector in the positive electrode, the same current collector as described in the negative electrode of the present invention can be used.

The material used for the positive electrode of the lithium ion secondary battery of the present invention (also referred to as positive electrode material) may be any compound that can be doped or intercalated with lithium ions, such as lithium cobaltate (LiCoO ₂ ), lithium nickelate. (LiNiO _2), and lithium manganate (LiMnO ₂₎ or the like.

The positive electrode is prepared by mixing a positive electrode material, an organic binder such as polyvinylidene fluoride, and a solvent such as N-methyl-2-pyrrolidone and γ-butyrolactone. It can be produced by applying to at least one surface of a current collector such as an aluminum foil, and then drying and removing the solvent, followed by pressure treatment as necessary.
In addition, you may add a conductive support agent to a positive electrode coating liquid. Examples of the conductive assistant include carbon black, acetylene black, conductive oxide, and conductive nitride. These conductive assistants may be used alone or in combination of two or more.

  The electrolyte solution used for the lithium ion secondary battery of the present invention is not particularly limited, and a known one can be used. For example, a non-aqueous lithium ion secondary battery can be manufactured by using a solution obtained by dissolving an electrolyte in an organic solvent as the electrolytic solution.

As _{the electrolyte, LiPF 6, LiClO 4, LiBF} 4, LiClF 4, LiAsF 6, LiSbF 6, LiAlO 4, LiAlCl 4, LiN (CF 3 SO 2) 2, LiN (C 2 F 5 SO 2) 2, LiC ( CF ₃ SO ₂ ) ₃ , LiCl, LiI and the like.

  The organic solvent only needs to dissolve the electrolyte, and examples thereof include propylene carbonate, ethylene carbonate, diethyl carbonate, ethyl methyl carbonate, vinyl carbonate, γ-butyrolactone, 1,2-dimethoxyethane, and 2-methyltetrahydrofuran.

  Various known separators can be used as the separator. Specific examples include a paper separator, a polypropylene separator, a polyethylene separator, a glass fiber separator, and the like.

  The method for producing the lithium ion secondary battery is not particularly limited. For example, it can be manufactured by the following steps. First, two electrodes, a positive electrode and a negative electrode, are wound through a separator. The obtained spiral wound group is inserted into a battery can, and a tab terminal previously welded to a negative electrode current collector is welded to the bottom of the battery can. Inject the electrolyte into the obtained battery can, weld the tab terminal that was previously welded to the positive electrode current collector to the battery lid, and place the lid on the top of the battery can via the insulating gasket A battery is obtained by caulking and sealing the part where the lid and the battery can are in contact.

  The form of the lithium ion secondary battery of the present invention is not particularly limited, and examples include lithium ion secondary batteries such as paper batteries, button batteries, coin batteries, stacked batteries, cylindrical batteries, and prismatic batteries. .

  The negative electrode material for a lithium ion secondary battery according to the present invention is not limited to a lithium ion secondary battery, and can be applied to all electrochemical devices having a charging / discharging mechanism for insertion / extraction of lithium ions.

  EXAMPLES Hereinafter, although a synthesis example, an Example, and a comparative example are given and this invention is demonstrated more concretely, this invention is not restrict | limited to the following Example. Unless otherwise specified, “part” and “%” are based on mass.

[Example 1]
(Preparation of negative electrode material)
Bulk silicon oxide (High Purity Chemical Laboratory Co., Ltd., standard 10 mm to 30 mm square) was coarsely pulverized with a mortar to obtain silicon oxide particles. The silicon oxide particles were further pulverized by a vibration mill (small vibration mill NB-0, Nichito Kagaku Co., Ltd.), and then sized with a 300M (300 mesh) test sieve, and silicon having an average particle diameter D50% of 5 μm. Oxide particles were obtained. The average particle size was measured by the following method.

<Measurement of average particle diameter>
A measurement sample (5 mg) was placed in a 0.01% by weight aqueous solution of a surfactant (Esomine T / 15, Lion Co., Ltd.) and dispersed with a vibration stirrer. The obtained dispersion was put into a sample water tank of a laser diffraction particle size distribution analyzer (SALD3000J, Shimadzu Corporation), circulated with a pump while applying ultrasonic waves, and measured by a laser diffraction method. The measurement conditions were as follows. The volume cumulative 50% particle size (D50%) of the obtained particle size distribution was defined as the average particle size. Hereinafter, in the examples, the average particle size was measured in the same manner.
・ Light source: Red semiconductor laser (690nm)
Absorbance: 0.10 to 0.15
-Refractive index: 2.00-0.20

  900 g of the obtained silicon oxide particles and 100 g of coal-based pitch (fixed carbon 50 mass%) are put into a mixing device (Rocking Mixer RM-10G, Aichi Electric Co., Ltd.), mixed for 5 minutes, and then heat-treated from alumina. The container was filled. After filling the heat treatment container, this was heat treated in an atmosphere firing furnace under a nitrogen atmosphere at 1000 ° C. for 5 hours to obtain a heat treated product.

  The obtained heat-treated product was crushed with a mortar, sieved with a 300M (300 mesh) test sieve, and the surface of the silicon oxide particles was coated with a simple substance of carbon, and an SiO— with an average particle diameter D50% of 5 μm. C particles were obtained.

<Measurement of carbon content>
The content ratio of carbon in the SiO—C particles was measured by high-frequency firing-infrared analysis. The high-frequency firing-infrared analysis method is an analysis method in which a sample is heated and burned with an oxygen stream in a high-frequency furnace, carbon and sulfur in the sample are converted into CO ₂ and SO ₂ , respectively, and quantified by an infrared absorption method. The measuring apparatus and measurement conditions are as follows.
・ Device: Simultaneous carbon sulfur analyzer (CSLS600, LECO Japan GK)
・ Frequency: 18MHz
・ High frequency output: 1600W
Sample weight: about 0.05g
・ Analysis time: Automatic mode is used in the setting mode of the device ・ Combustible material: Fe + W / Sn
Standard sample: Leco 501-224 (C: 3.03% ± 0.04 S: 0.055% ± 0.002)
97
-Number of measurements: 2 times (the value of carbon simple substance content in Tables 1 and 2 is the average value of the two measurements)

<Measurement of crystallite size of silicon>
The negative electrode material was analyzed using a powder X-ray diffractometer (MultiFlex (2 kW), Rigaku Corporation). The size of the silicon crystallite was calculated from the half width of the peak attributed to the crystal plane of Si (111) existing in the vicinity of 2θ = 28.4 °, using the Scherrer equation.
The measurement conditions were as follows.

-Radiation source: CuKα ray (wavelength: 0.154056 nm)
Measurement range: 2θ = 10 ° to 40 °
・ Sampling step width: 0.02 °
・ Scanning speed: 1 ° / min ・ Tube current: 40 mA
・ Tube voltage: 40kV
・ Divergent slit: 1 °
・ Scatter slit: 1 °
・ Reception slit: 0.3mm

  The obtained profile was subjected to background (BG) removal and peak separation using the structure analysis software (JADE6, Rigaku Corporation) attached to the above apparatus with the following settings.

[Kα2 peak removal and background removal]
・ Kα1 / Kα2 intensity ratio: 2.0
BG curve up and down (σ) from BG point: 0.0

[Specify peak]
-Peak attributed to Si (111): 28.4 ° ± 0.3 °
・ Peak attributed to SiO ₂ : 21 ° ± 0.3 °

[Peak separation]
Profile shape function: Pseudo-Voigt
・ Background fixed

The full width at half maximum of the peak attributed to Si (111) derived from the structure analysis software with the above settings was read, and the size of the silicon crystallite was calculated from the following Scherrer equation.
D = Kλ / B cos θ
B = ( _Bobs ² −b ² ) ^1/2
D: Size of crystallite (nm)
K: Scherrer constant (0.94)
λ: Source wavelength (0.154056 nm)
θ: Measurement half-width peak angle B _obs : Half-width (measured value obtained from structural analysis software)
b: Measurement half width of standard silicon (Si)

  Next, scaly graphite (KS-6, Timcal) and acetylene black (HS100, Denki Kagaku Kogyo Co., Ltd.) having an average particle diameter D50% of 3 μm were prepared as conductive particles.

  To 800 g of water, 150 g of flaky graphite (KS-6, Timcal), 40 g of acetylene black (HS100, Denki Kagaku Kogyo Co., Ltd.) and 10 g of carboxymethylcellulose are dispersed and mixed in a bead mill, A dispersion (solid content: 25% by mass) was obtained.

  Next, after adding 100 g of the obtained dispersion liquid of conductive particles to 450 g of water and thoroughly stirring with a stirrer, 500 g of SiO-C particles are added and further stirred to disperse the SiO-C particles and conductive particles dispersed. A liquid was obtained.

  The liquid in which the obtained SiO—C particles and conductive particles were dispersed was put into a dryer, and dried at 150 ° C. for 12 hours to remove water. As a result, SiO—C particles having conductive particles attached to the surface were obtained. Thereafter, the mixture was crushed with a mortar and then sieved with a 300 mesh test sieve to obtain a negative electrode material having an average particle diameter D50% of 5.5 μm.

<Measurement of content of conductive particles>
The content rate of electroconductive particle was measured with the high frequency baking-infrared analysis method. In this measurement, since the content of simple carbon in the SiO—C particles is included, the content of simple carbon was measured in advance by high-frequency firing-infrared analysis. The measurement was carried out in the same manner as the above-described method for measuring the content of single carbon.

<Measurement of BET specific surface area of negative electrode material>
Using a high-speed specific surface area / pore distribution measuring device (ASAP2020, Micromeritics Japan GK), nitrogen adsorption at a liquid nitrogen temperature (77K) was measured by a five-point method, and the BET method (relative pressure range: 0.05). To 0.2).

(Production method of negative electrode)
The negative electrode material powder (97.6 parts by mass), carboxymethylcellulose (CMC) (1.2 parts by mass), and styrene-butadiene rubber (SBR, 1.2 parts by mass) produced by the above method are kneaded to obtain a uniform slurry. Was made. This slurry is applied to the glossy surface of the electrolytic copper foil so that the coating amount is 10 mg / cm ² , preliminarily dried at 90 ° C. for 2 hours, and then the density is 1.65 g / cm ³ with a roll press. Adjusted. Thereafter, a curing treatment was performed by drying at 120 ° C. for 4 hours in a vacuum atmosphere to obtain a negative electrode.

(Production of lithium ion secondary battery)
The electrode obtained above was used as a negative electrode, metallic lithium as a counter electrode, ethylene carbonate (EC), diethyl carbonate (DEC) and ethyl methyl methyl carbonate (EMC) containing 1M LiPF ₆ as an electrolyte (volume ratio 1: 1: A 2016 type coin cell was prepared using a mixed liquid of 1) and vinylene carbonate (VC) (1.0 mass%), a polyethylene microporous film having a thickness of 25 μm as a separator, and a copper plate having a thickness of 250 μm as a spacer.

(Battery evaluation)
<Initial charge capacity, initial discharge capacity, charge / discharge efficiency>
The resultant battery above, placed in a constant temperature bath maintained at 25 ℃, 0.45mA / cm ² after the constant current charging until 0V, the current at a constant voltage of 0V is 0.09 mA / cm ² The battery was further charged until it decayed to a value corresponding to, and the initial charge capacity was measured. After charging, the battery was discharged after a 30-minute pause. Discharge was performed at 0.45 mA / cm ² until the voltage reached 1.5 V, and the initial discharge capacity was measured. At this time, the capacity was converted per mass of the negative electrode material used. A value obtained by dividing the initial discharge capacity by the initial charge capacity was calculated as the initial charge / discharge efficiency (%). The results are shown in Table 1.

<Cycle characteristics>
Each battery obtained above was placed in a thermostat kept at 25 ° C., charged at 0.45 mA / cm ² until it became 0 V, and then at a constant voltage of 0 V, the current was 0.09 mA / cm. ^The battery was further charged until it decayed to a value corresponding to ² . After charging, the battery was discharged after a 30-minute pause. Discharging was performed at 0.45 mA / cm ² until 1.5V was reached. The cycle characteristics (%) calculated by the following formula was evaluated by performing the cycle test 10 times with this charge-discharge as one cycle. The results are shown in Table 1.
Formula: cycle characteristics = discharge capacity at the 10th cycle / discharge capacity at the 1st cycle

[Comparative Example 1]
A negative electrode material was obtained in the same manner as in Example 1 except that the step of attaching the conductive particles to the surface of the SiO—C particles was not performed. And using the obtained negative electrode material, it carried out similarly to Example 1, produced the 2016 type coin cell, and evaluated similarly to Example 1. FIG. The results are shown in Table 1.

[Example 2]
A negative electrode material was obtained in the same manner as in Example 1 except that the conductive particles were only scaly graphite (KS-6, Timcal). And using the obtained negative electrode material, it carried out similarly to Example 1, produced the 2016 type coin cell, and evaluated similarly to Example 1. FIG. The results are shown in Table 1.

[Example 3]
A negative electrode material was obtained in the same manner as in Example 1 except that the conductive particles were only acetylene black (HS100, Denki Kagaku Kogyo Co., Ltd.). And using the obtained negative electrode material, it carried out similarly to Example 1, produced the 2016 type coin cell, and evaluated similarly to Example 1. FIG. The results are shown in Table 1.

[Example 4]
A negative electrode material was obtained in the same manner as in Example 1 except that the dispersion of conductive particles was changed to 200 g. And using the obtained negative electrode material, it carried out similarly to Example 1, produced the 2016 type coin cell, and evaluated similarly to Example 1. FIG. The results are shown in Table 2.

[Example 5]
A negative electrode material was obtained in the same manner as in Example 1 except that in the step of coating the carbon alone, the silicon oxide particles were 800 g and the coal-based pitch (fixed carbon 50 mass%) was 200 g. And using the obtained negative electrode material, it carried out similarly to Example 1, produced the 2016 type coin cell, and evaluated similarly to Example 1. FIG. The results are shown in Table 2.

[Example 6]
A negative electrode material was obtained in the same manner as in Example 1 except that the heat treatment temperature was set to 1050 ° C. in the step of coating the carbon alone. And using the obtained negative electrode material, it carried out similarly to Example 1, produced the 2016 type coin cell, and evaluated similarly to Example 1. FIG. The results are shown in Table 2.

  From the results of Tables 1 and 2, the negative electrode materials for lithium ion secondary batteries shown in Examples 1 to 6 have excellent initial discharge capacity and initial charge / discharge efficiency, and the conductive particles are made of SiO-C particles. It can be seen that the material is superior in cycle characteristics as compared with Comparative Example 1 which does not adhere to the surface.

10 Carbon simple substance 12 Carbon simple substance particle 14 Conductive particle 20 Silicon oxide particle

Claims (8)

  Silicon oxide particles, carbon simple substance existing on a part or all of the surface of the silicon oxide particles, and granular graphite and carbon black adhering to the surface of the silicon oxide particles where the carbon simple substance exists on the surface A negative electrode material for a lithium ion secondary battery, comprising a kind of conductive particles selected from the group consisting of:   The negative electrode material for a lithium ion secondary battery according to claim 1, wherein the conductive particles include at least the granular graphite.   The negative electrode material for a lithium ion secondary battery according to claim 2, wherein the granular graphite is flat graphite.   The content rate of the said electroconductive particle is 1.0 mass%-10.0 mass%, The negative electrode material for lithium ion secondary batteries of any one of Claims 1-3.   The negative electrode material for a lithium ion secondary battery according to any one of claims 1 to 4, wherein a content rate of the simple carbon is 0.5 mass% to 10.0 mass%.   An X-ray diffraction spectrum using CuKα rays as a radiation source has a diffraction peak attributed to Si (111), and the silicon crystallite size calculated from the diffraction peak is 2.0 nm to 8.0 nm. The negative electrode material for lithium ion secondary batteries according to any one of claims 1 to 5.   A lithium ion battery comprising: a current collector; and a negative electrode material layer comprising the negative electrode material for a lithium ion secondary battery according to any one of claims 1 to 6 provided on the current collector. Negative electrode for secondary battery.   A lithium ion secondary battery comprising: a positive electrode; a negative electrode for a lithium ion secondary battery according to claim 7; and an electrolyte.