WO2011125834A1 - 正極活物質 - Google Patents
正極活物質 Download PDFInfo
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- WO2011125834A1 WO2011125834A1 PCT/JP2011/058205 JP2011058205W WO2011125834A1 WO 2011125834 A1 WO2011125834 A1 WO 2011125834A1 JP 2011058205 W JP2011058205 W JP 2011058205W WO 2011125834 A1 WO2011125834 A1 WO 2011125834A1
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- C01G45/1228—Manganates or manganites with a manganese oxidation state of Mn(III), Mn(IV) or mixtures thereof of the type [MnO2]n-, e.g. LiMnO2, Li[MxMn1-x]O2
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Definitions
- the present invention relates to a positive electrode active material.
- the power source for electric vehicles is required to have a large battery capacity, low cycle deterioration, high-speed charge / discharge, etc. as characteristics, and a lithium ion secondary battery (hereinafter referred to as Li ion secondary battery). Also called a battery).
- Li ion secondary battery also called a battery.
- lithium cobaltate As a positive electrode active material of a Li ion secondary battery, the battery capacity of lithium cobaltate is about 150 mAh / g, which is a relatively large capacity. However, lithium cobaltate is not used in electric vehicle applications because of its high activity and a problem with safety at high temperatures and overcharge.
- Patent Document 1 for the purpose of providing an all solid lithium secondary battery having a large capacity and excellent charge / discharge cycle characteristics, amorphous V 2 O 5 —P 2 O 5 is used as the positive electrode active material. A technique using is disclosed.
- Patent Document 2 discloses a technique for reducing the average crystallite size of crystals such as lithium iron phosphate and lithium manganese phosphate having an olivine crystal structure to 140 nm or less for the purpose of obtaining good charge / discharge capacity and good load characteristics. Is disclosed.
- Patent Document 3 for the purpose of obtaining high discharge rate characteristics, discharge current, and battery output, at least one of glass and glass ceramics made of lithium-containing iron vanadium phosphate containing at least one of Co, Mn, and Ni is used. A technique using an electrode active material mainly composed of s is disclosed.
- Patent Document 4 Co, Ni, Fe, V, Cr, and the like are provided for the purpose of providing a positive electrode active material that maintains good positive electrode performance even when continuously used at a charging voltage of 4 V or higher in a high temperature environment.
- a technique using a spinel type lithium manganese oxide in which Mn is substituted with at least one transition metal selected from Ti is disclosed.
- Patent Document 5 discloses a composite oxide of vanadium and lithium or a first transition metal in a positive electrode active material for the purpose of constituting a lithium secondary battery having a large charge / discharge capacity, a high energy density, and a long cycle life. A technique for coexisting an amorphous phase and a crystalline phase is disclosed.
- JP-A-5-47386 Japanese Patent No. 4058680 JP 2009-16277 A JP 9-35712 A Japanese Patent No. 29783030
- An object of the present invention is to provide a positive electrode active material that has high safety when used in a lithium ion secondary battery, high charge / discharge cycle maintenance ratio, and high capacity.
- the positive electrode active material of the present invention includes a crystal phase formed of a plurality of crystallites and an amorphous phase formed in contact with the crystallites, and the amorphous phase includes vanadium oxide and iron oxide. Including one or more metal oxides selected from the group consisting of manganese oxide, nickel oxide and cobalt oxide, wherein the crystalline phase and the amorphous phase are capable of inserting and desorbing lithium ions.
- the present invention it is possible to provide a positive electrode active material that has a high cycle maintenance ratio in a lithium ion secondary battery and increases the battery capacity.
- Example positive electrode active material No. It is an SEM image of 1-3.
- 2B is an enlarged SEM image of the positive electrode active material shown in FIG. 2A. It is a schematic diagram of the SEM image of FIG. 2A. It is a schematic diagram of the enlarged SEM image of FIG. 2B. No. in the example. It is an EDX analysis result of 1-3 amorphous phase. It is sectional drawing which shows the structure of the lithium ion secondary battery of an Example. It is a schematic sectional drawing which shows a lithium ion doping apparatus.
- the positive electrode active material includes a crystal phase having a structure formed by aggregating a plurality of crystallites and an amorphous phase formed in contact with the crystallites, and the amorphous phase is oxidized Contains one or more metal oxides selected from the group consisting of vanadium, iron oxide, manganese oxide, nickel oxide and cobalt oxide, and the crystalline phase and the amorphous phase can insert and desorb lithium ions It is.
- the amorphous phase is formed in contact with the crystallite. More specifically, in the powder particle of the positive electrode active material, the surface region of the powder particle, that is, the powder particle and the outside (gas phase or liquid phase) are in contact. The region is formed in the crystallite grain boundary region as shown in the examples described later.
- the grain boundary region means a region sandwiched between crystallites, and it can be said that the amorphous phase is formed in the grain boundary region.
- the grain boundary means an interface of crystallites.
- the embodiment of the present invention includes a positive electrode active material that does not include an amorphous phase between crystallites and that has an amorphous phase only in the surface region of the powder particle.
- the grain boundary region of the crystal phase is filled with an amorphous phase formed between crystallites. That is, it is preferable that the crystal phase has a structure covered with an amorphous phase. In the present invention, there may be a portion where crystallites are in direct contact to form a grain boundary.
- the amorphous phase is formed in a grain boundary region sandwiched between crystallites. Furthermore, the amorphous phase may be formed on the surface of the powder particles of the positive electrode active material including the crystalline phase and the amorphous phase, that is, at the interface between the powder particles and the gas phase.
- the lithium ion can be inserted and removed not only in the crystalline phase but also in the amorphous phase, and the crystalline phase is covered with the amorphous phase. Insertion and desorption into the phase are performed via the amorphous phase, the crystalline phase contributes as the capacity of the battery, and the amorphous phase also contributes as the capacity of the battery. For this reason, deterioration of the crystal phase due to insertion and desorption of lithium ions is suppressed, and the charge / discharge cycle maintenance rate can be improved.
- the crystalline phase and the amorphous phase form powder particles.
- the amorphous phase contains phosphorus oxide.
- the amorphous phase contains vanadium oxide.
- the amorphous phase includes at least one metal oxide of iron oxide and manganese oxide.
- the content of the amorphous phase in the powder particles is 6% by volume or more.
- the content of vanadium, iron, manganese, nickel, and cobalt in the amorphous phase is 0.5 to 9.0 in terms of atomic ratio with respect to the content of phosphorus in the amorphous phase. is there.
- the crystallite includes an oxide of one or more metals selected from the group consisting of iron, manganese, and vanadium.
- the crystallite is X y V 2 O 5 (where X is one kind of metal selected from the group consisting of Li, Na, K, Cu, Ag and Fe, and y is , 0.26 to 0.41).
- the average crystallite size of the crystallite is 300 nm or less.
- the powder particles are obtained by a crystallization process by heat treatment of an oxide glass containing one kind of metal selected from the group consisting of vanadium, iron, manganese, nickel, and cobalt and phosphorus.
- the oxide glass contains a monovalent cation element.
- the positive electrode active material is formed by inserting lithium ions into the powder particles after the crystallization step.
- the positive electrode active material further contains carbon.
- FIG. 1A is a schematic diagram illustrating a fine structure of a positive electrode active material (conductive material) of an example.
- FIG. 1B is a schematic diagram further enlarging the fine structure of the positive electrode active material of FIG. 1A.
- a crystal of a positive electrode active material has a structure including a secondary particle 102 and an amorphous phase 103a (also referred to as an amorphous oxide phase), and is not in a gap between adjacent secondary particles 102.
- a crystalline phase 103a is formed.
- “adjacent” means “adjacent to each other”.
- the primary particles 101 of the crystal are aggregated to form secondary particles 102 shaped like a bunch of grapes.
- An amorphous phase 103 a is formed around the secondary particles 102.
- a fine amorphous phase 103b (represented by a solid line because it is a very narrow region) is formed in the gap between adjacent primary particles 101.
- the amorphous phase 103 has a low battery capacity.
- the amorphous phase 103 not only plays a role of increasing the diffusion rate of Li ions that go back and forth between the grain boundary region and the crystallite during charging and discharging, but also amorphous.
- the number of Li ions that can be inserted into the structure of the mass phase 103 is large. Therefore, not only the cycle maintenance rate of the positive electrode active material can be improved, but also the battery capacity can be improved.
- the proportion of the amorphous phase of the positive electrode active material for Li ion secondary batteries is preferably 6% by volume or more.
- the amount of the amorphous phase 103 is larger.
- the proportion of the amorphous phase 103 is less than 6% by volume, the cycle retention rate of the positive electrode active material is lowered.
- the positive electrode active material can contain carbon.
- the added carbon can be coated on the powder surface of the positive electrode active material in addition to the powder form, and both are added to adjust the electric resistance of the positive electrode active material.
- the amorphous phase of the positive electrode active material includes at least one metal oxide selected from the group consisting of vanadium oxide, iron oxide, manganese oxide, nickel oxide, and cobalt oxide.
- An oxide of at least one metal selected from the group consisting of vanadium oxide, iron oxide, manganese oxide, nickel oxide, and cobalt oxide is a component that forms an amorphous phase, and is a compound oxide crystal of lithium.
- a positive electrode active material has been studied as a component.
- phosphorus oxide or silicon oxide can be further included.
- Vanadium, iron, manganese, nickel, and cobalt have been studied as positive electrode active materials as components of complex oxide crystals with phosphorus and lithium, and high charge / discharge characteristics even when the complex oxide crystals are in an amorphous state. Indicates.
- Iron, manganese, nickel, and cobalt have been studied as positive electrode active materials as components of composite oxide crystals with silicon and lithium, and show high charge / discharge characteristics even when the composite oxide crystals are in an amorphous state. .
- the amorphous phase containing phosphorus, vanadium, iron, manganese, nickel and cobalt contained in the amorphous phase are 0 in atomic ratio (atomic ratio) to phosphorus contained in the amorphous phase. It is preferably from 5 to 9.0.
- atomic ratio 0.5 to 9.0
- the effect of improving the battery capacity and the cycle retention ratio is strong.
- the atomic ratio is less than 0.5 or greater than 9.0, the structure of the amorphous phase becomes unstable with respect to charge / discharge, and the effect of improving the battery capacity and cycle retention rate is reduced.
- Crystallite The crystallite of the positive electrode active material is an oxide phase containing a transition metal.
- the crystallite is required to have a large capacity.
- the transition metal contains vanadium, iron, manganese, cobalt and nickel.
- the crystallite containing vanadium preferably contains a monoclinic X y V 2 O 5 crystal.
- the monoclinic X y V 2 O 5 crystal has a cylindrical structure in which cations (X) are regularly bonded between layers of the vanadium oxide layered structure.
- X is preferably any one of Li, Na, K, Cu, Ag, and Fe from the viewpoint of safety and availability.
- y is 0.26 to 0.41. If y is too small, the crystal structure becomes weak, and the cycle retention rate decreases. In addition, as y increases, the space for entering Li ions decreases, and the battery capacity decreases.
- iron, manganese, crystals containing nickel and cobalt LiFePO 4, LiMnPO 4, LiMn 2 O 4, LiCoPO 4, LiNiPO 4, LiCoO 2, LiNiO 2, LiCoVO 4, LiNiVO 4, LiMnO 2, Li 2 FeSiO 4 , Li 2 MnSiO 4 , Li 2 CoSiO 4 , Li 2 NiSiO 4 and the like are desirable.
- Any of the crystals has a structure in which Li ions can be inserted, and has high battery characteristics.
- the average crystallite size of the above crystal is desirably 300 nm or less. If the crystallite size is too large, the movement distance of Li ions becomes large, and the charge / discharge rate becomes slow.
- the average crystallite size is preferably 5 nm or more, and more preferably 10 nm or more.
- a positive electrode active material is obtained by heat-processing the oxide glass containing 1 or more types of metals among vanadium, iron, manganese, nickel, and cobalt.
- the amorphous phase containing phosphorus can form oxide glass by melting and quenching by mixing phosphorus powder with one or more metals of vanadium, iron, manganese, nickel and cobalt. Of these metals, one or more metal elements selected from the group consisting of vanadium, iron, and manganese that can form an amorphous phase that is stable to charge and discharge are preferable.
- the amorphous phase containing silicon can be produced in the same manner by mixing one or more metals among iron, manganese, nickel and cobalt with silicon oxide powder.
- a monovalent cation element can be further added to the oxide glass.
- a monovalent cation is a component for producing crystallites by heat treatment.
- Crystallites can be generated in the oxide glass by heat-treating the oxide glass at a crystallization start temperature or higher. Since this crystallite is generated in two stages of crystal nucleus generation and crystal growth, the crystal state generated differs depending on the heat treatment conditions.
- crystallite diameter crystallite diameter
- the crystallite is kept long at the crystal nucleation temperature, and crystal nuclei are sufficiently precipitated and then grown.
- a method is generally used in which the crystal nucleation temperature is passed quickly and the crystal is grown while keeping the number of crystal nuclei at a high temperature.
- the amorphous phase can be present in the structure of the oxide glass even after heat treatment by controlling the precipitation and growth of crystallites.
- the composition of the amorphous phase is different from the oxide glass before the heat treatment because the ratio of components precipitated as crystallites is small.
- Table 1 shows the glass compositions prepared and studied.
- All components are expressed in mass% (mass percent) in terms of oxide.
- the raw materials for each component are vanadium pentoxide, phosphorus pentoxide, ferric oxide, manganese dioxide, cuprous oxide, cuprous oxide, cobalt oxide, nickel oxide, tungsten oxide, molybdenum oxide, boron oxide and silicon oxide. is there.
- Lithium carbonate, sodium carbonate, and potassium carbonate were used for lithium, sodium, and potassium.
- the oxide glass was produced according to the following procedure.
- 300 g of the mixed powder prepared by mixing and mixing the raw material compounds so as to have the composition shown in Table 1 is put in a platinum crucible and heated at a rate of 5 to 10 ° C./min (° C./min) using an electric furnace. Each was heated to the heating temperature and held for 2 hours. During holding, stirring was performed to obtain a uniform glass. Next, the platinum crucible was taken out from the electric furnace and poured onto a stainless steel plate heated to 200 to 300 ° C. in advance to obtain an oxide glass.
- the oxide glass shown in Table 1 was processed into a size of 10 ⁇ 10 ⁇ 4 mm to obtain a sample piece. This sample piece was placed on an alumina substrate and No. 1-4, no. 1-18 and No.1. The oxide glass of 1-23 was heated in an electric furnace at 250 ° C. for 50 hours. 1-4, no. 1-18 and No.1. The oxide glass except 1-23 was heated at 420 ° C. for 50 hours to precipitate crystallites in the oxide glass.
- SEM is an abbreviation for Scanning Electron Microscope: Scanning Electron Microscope
- EDX is an abbreviation for Energy Dispersive X-ray Spectrometer: Energy Dispersive X-ray Analyzer.
- FIG. 2A shows No. with crystallites deposited. It is an SEM image of 1-3.
- FIG. 2B is an enlarged image of FIG. 2A.
- 2C is a schematic diagram of the SEM image of FIG. 2A, and
- FIG. 2D is a schematic diagram of the SEM image of FIG. 2B.
- the primary particles 101 of the crystal aggregate to form secondary particles 102 shaped like a bunch of grapes, and an amorphous phase 103 is formed in the grain boundary region of the secondary particles 102.
- FIG. 3 shows a composition analysis result obtained by performing SEM-EDX analysis on a part of the amorphous phase shown in the SEM image of FIG. 2B.
- transition metals contained in the amorphous phase of 1-3 are found to be vanadium and iron, and the ratio of vanadium and iron contained in the amorphous part to phosphorus is based on the number of atoms (atomic ratio) as follows: It can be obtained from the calculation formula.
- vanadium and iron contained in the 1-3 amorphous phase contained 1.8 in terms of phosphorus (atomic ratio).
- the sample shown in Table 1 was similarly subjected to SEM-EDX analysis to identify transition metals contained in the amorphous state.
- the ratio (atomic ratio) of vanadium, iron, manganese, nickel and cobalt contained in the amorphous phase to phosphorus was measured.
- the X-ray source was Cu, and its output was set to 50 kV and 250 mA.
- a concentrated optical system with a monochromator was used, and a divergence slit of 0.5 deg, a receiving slit of 0.15 mm, and a scattering slit of 0.5 deg were selected.
- the scanning axis of X-ray diffraction was a 2 ⁇ / ⁇ interlocking type, and measurement was performed in a range of 5 ⁇ 2 ⁇ ⁇ 100 deg by continuous scanning under conditions of a scanning speed of 1.0 deg / min and sampling of 0.01 deg.
- the amorphous ratio was calculated from the ratio between the amorphous halo and the crystal-derived diffraction peak in the obtained diffraction pattern. This ratio is considered to represent the volume ratio of the amorphous phase and the crystallite.
- the diffraction peak due to the crystal cannot be detected if the crystallite contained in the measurement sample is too small on the measurement principle.
- the size of the crystallite (crystallite diameter) included in the measurement sample is 5 nm or less, a diffraction peak due to the crystal is not detected. Therefore, even if the measurement sample has an amorphous ratio of 100%, it does not indicate that the measurement sample does not contain crystallites.
- crystals precipitated in the material were identified using ICDD data which is a collection of X-ray diffraction standard data.
- the main crystals identified are V 2 O 5 crystal, Li 0.3 V 2 O 5 crystal, Na 0.287 V 2 O 5 crystal, Ag 0.33 V 2 O 5 crystal, K 0.33 V 2. They were O 5 crystal, Cu 0.261 V 2 O 5 crystal, Cu 0.41 V 2 O 5 crystal, Fe 0.33 V 2 O 5 crystal, LiMnO 2 crystal and Li 2 FeSiO 4 crystal.
- the diffraction peak having the highest peak intensity among the diffraction peaks derived from the identified crystals was used as the main detection peak.
- the (001) plane was used, and Li 0.3 V 2 O 5 crystal, Na 0.287 V 2 O 5 crystal, Ag 0.33 V 2 O 5 crystal, K 0.33 V 2
- the O 5 crystal Cu 0.261 V 2 O 5 crystal, Cu 0.41 V 2 O 5 crystal and Fe 0.33 V 2 O 5 crystal, the (111) plane is used, and for the LiMnO 2 crystal, (101)
- the face the (011) face was used for the Li 2 FePO 2 crystal, and the crystallite diameter was calculated therefrom.
- the following is a method for measuring the crystallite diameter.
- ⁇ Detailed measurement was performed by narrow scan at an angle near the detected main peak.
- integrated scanning was used as the scanning method.
- the scanning range was measured in the vicinity of the detected main peak.
- the crystallite size was calculated from the half width of the detected main peak obtained by narrow scan by the Scherrer equation.
- sample number 1-1 in Table 1 corresponds to sample number 2-1 in Table 2.
- Example 2 the sample described as “Example” is a preferred specific example of the present invention, and contains one or more kinds of metals of vanadium, iron, manganese, nickel and cobalt in the amorphous phase,
- the amorphous ratio is 6% by volume or more.
- No. 1 which is an example containing phosphorus. 2-3 ⁇ No. 2-17, no. 2-19 to No. 2 2-22 and no.
- vanadium, iron, manganese, nickel and cobalt contained in the amorphous phase have an atomic ratio of 0.5 to 9.0 with respect to phosphorus.
- the main crystals (mainly precipitated crystals) contained in the sample described as “Example” are V 2 O 5 , Li 0.3 V 2 O 5 , Na 0.287 V 2 O 5 crystals, Ag 0. 33 V 2 O 5 crystal, K 0.33 V 2 O 5 crystal, Cu 0.261 V 2 O 5 crystal, Cu 0.41 V 2 O 5 crystal, Fe 0.33 V 2 O 5 crystal, LiMnO 2 crystal And Li 2 FeSiO 4 crystals.
- the crystallite diameter is 300 nm or less.
- FIG. 4 is a schematic diagram showing an example of a lithium ion battery.
- a description will be given with reference to FIG. 4
- a positive electrode layer 7 including a positive electrode active material 2 and a conductive auxiliary agent 3 is formed on the surface of the positive electrode current collector 1, and these constitute a positive electrode 9. Further, a negative electrode layer 8 including the negative electrode active material 5 is formed on the surface of the negative electrode current collector 6, and these constitute the negative electrode 10.
- the negative electrode layer 8 was formed on the copper foil of the negative electrode current collector 6 using the negative electrode active material 5, further roll-pressed, and punched out in the same manner as the positive electrode 9 to produce the negative electrode 10.
- the coin cell was charged and discharged in the range of 4.5 to 2 V (vs. Li / Li + ) at a current density of 0.2 mA / cm 2 , and the initial capacity, discharge average voltage, energy The density and the capacity retention after 50 cycles were measured.
- Table 3 shows the results of battery evaluation.
- the energy density is “x” when less than 700 mAh / g, “ ⁇ ” when 700 mAh / g or more, and the cycle maintenance rate is “ ⁇ ” when less than 70%, and “ ⁇ ” when 70% or more and less than 80%. ”, With 80% or more being“ ⁇ ”, the worse result in both judgments was expressed as“ judgment of battery characteristics ”which is a comprehensive judgment.
- the crystal phase has a large charge / discharge capacity (initial capacity), but the charge / discharge cycle maintenance rate is low because the crystal phase changes to an amorphous phase by repeated charge / discharge. For this reason, it has been a problem to increase the charge / discharge cycle maintenance rate of the crystal phase.
- the amorphous phase was conventionally considered to have a low charge / discharge capacity. As shown in 2-4, it was found that the initial capacity and energy density were large. That is, it was found that an amorphous phase having a specific structure as shown in the examples has a large initial capacity and energy density.
- the example is characterized by the amorphous phase in the grain boundary region of the crystallite, and the type of crystal is not selected. Therefore, LiFePO 4, LiMnPO 4, LiMn 2 O 4, LiCoPO 4, LiNiPO 4, LiCoO 2, LiNiO 2, LiCoVO 4, LiNiVO 4, Li 2 FeSiO 4, Li 2 MnSiO 4, Li 2 CoSiO 4, Li 2 NiSiO It is clear that the same effect can be obtained for crystals such as 4 that can be produced from an amorphous material.
- FIG. 5 shows a lithium ion doping apparatus.
- the lithium ion doping apparatus 11 is made of SUS, and can heat the left and right sides of the reaction vessel 14 independently while evacuating the inside.
- the lithium ion doping apparatus 11 is installed in a glove box purged with nitrogen gas. 2-3 g of positive electrode active material (reference numeral 12) and 5 g of metallic lithium (reference numeral 13) were inserted into the reaction vessel 14 so as not to contact each other. The left portion of the reaction vessel 14 in which the positive electrode active material 12 was inserted was heated with a ribbon heater and evacuated for 3 hours. Subsequently, the valve of the reaction vessel 14 was closed and removed from the vacuum line, and the reaction was carried out for 2 weeks by heating to 350 ° C. with a mantle heater.
- the initial capacity was 353 mAh / g
- the operating average voltage was 2.5 V
- the energy density was 883 mWh / g
- the cycle retention rate was 91%, indicating high characteristics.
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Abstract
Description
図1Aは、実施例の正極活物質(導電性材料)の微細構造を示す模式図である。また、図1Bは、図1Aの正極活物質の微細構造を更に拡大して示す模式図である。
正極活物質の非晶質相は、酸化バナジウム、酸化鉄、酸化マンガン、酸化ニッケル及び酸化コバルトからなる群から選択される少なくとも一種類の金属酸化物を含む。
また、リンを含有する非晶質相については、非晶質相に含まれるバナジウム、鉄、マンガン、ニッケル及びコバルトが、非晶質に含まれるリンに対してアトミック比(原子数比)で0.5~9.0であることが好ましい。アトミック比が0.5~9.0の場合、電池容量及びサイクル維持率を向上させる効果が強く現れる。アトミック比が0.5未満の場合、若しくは9.0よりも大きい場合、非晶質相の構造が充放電に対して不安定になり、電池容量及びサイクル維持率を向上させる効果が低下する。
正極活物質の結晶子は、遷移金属を含む酸化物相である。
いずれの結晶も、Liイオンを挿入可能な構造であり、高い電池特性を有する結晶である。
正極活物質は、バナジウム、鉄、マンガン、ニッケル及びコバルトのうち1種類以上の金属を含む酸化物ガラスを熱処理することにより得られる。
表1は、作製・検討したガラス組成を示したものである。
表1に示す酸化物ガラスを10×10×4mmのサイズに加工して試料片とした。この試料片をアルミナ基板に載せて、No.1-4、No.1-18及びNo.1-23の酸化物ガラスは250℃の電気炉で50時間加熱し、No.1-4、No.1-18及びNo.1-23を除く酸化物ガラスは420℃で50時間加熱し、酸化物ガラス中に結晶子を析出させた。
次いで、SEM-EDXを用いて結晶子及び非晶質相の観察及び組成分析を行った。ここで、SEMは、Scanning Electron Microscope:走査型電子顕微鏡の略称であり、EDXは、Energy Dispersive X-ray Spectrometer:エネルギー分散型X線分析装置の略称である。
次いで、表1に示す試料を平均粒径5μmの粉末に粉砕し、得られた粉末の結晶状態を評価した。広角X線回折装置(リガク製、RINT2500HL)を使用して非晶質率の測定し、結晶の同定及び結晶子径の測定を行った。結晶の同定及び非晶質率の測定条件は次の通りである。
次に、Liイオン二次電池の評価について説明する。
図5にリチウムイオンドープ装置を示す。
Claims (14)
- 複数個の結晶子で形成された結晶相と、前記結晶子と接して形成された非晶質相とを含み、前記非晶質相は、酸化バナジウム、酸化鉄、酸化マンガン、酸化ニッケル及び酸化コバルトからなる群から選択される1種類以上の金属酸化物を含み、前記結晶相及び前記非晶質相は、リチウムイオンの挿入及び脱離が可能であることを特徴とする正極活物質。
- 前記結晶相及び前記非晶質相が粉末粒子を形成していることを特徴とする請求項1記載の正極活物質。
- 前記非晶質相は、酸化リンを含むことを特徴とする請求項1又は2に記載の正極活物質。
- 前記非晶質相は、酸化バナジウムを含むことを特徴とする請求項3記載の正極活物質。
- 前記非晶質相は、酸化鉄及び酸化マンガンのうち少なくともいずれか1種類の金属酸化物を含むことを特徴とする請求項1~4のいずれか一項に記載の正極活物質。
- 前記粉末粒子における前記非晶質相の含有量が6体積%以上であることを特徴とする請求項2~5のいずれか一項に記載の正極活物質。
- 前記非晶質相におけるバナジウム、鉄、マンガン、ニッケル及びコバルトの含有量が、非晶質相におけるリンの含有量に対してアトミック比で0.5~9.0であることを特徴とする請求項1~6のいずれか一項に記載の正極活物質。
- 前記結晶子は、鉄、マンガン及びバナジウムからなる群から選択される1種類以上の金属の酸化物を含むことを特徴とする請求項1~7のいずれか一項に記載の正極活物質。
- 前記結晶子は、XyV2O5(ただし、Xは、Li、Na、K、Cu、Ag及びFeからなる群から選択される1種類の金属であり、yは、0.26~0.41である。)であることを特徴とする請求項8記載の正極活物質。
- 前記結晶子の平均結晶子サイズが300nm以下であることを特徴とする請求項1~9のいずれか一項に記載の正極活物質。
- 前記粉末粒子は、バナジウム、鉄、マンガン、ニッケル及びコバルトからなる群から選択される1種類の金属と、リンとを含む酸化物ガラスの熱処理による結晶化工程によって得られることを特徴とする請求項2~10のいずれか一項に記載の正極活物質。
- 前記酸化物ガラスは、一価の陽イオン元素を含むことを特徴とする請求項11記載の正極活物質。
- 前記結晶化工程の後、前記粉末粒子にリチウムイオンを挿入することによって形成されたことを特徴とする請求項11又は12に記載の正極活物質。
- さらに、カーボンを含むことを特徴とする請求項1~13のいずれか一項に記載の正極活物質。
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Cited By (5)
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EP2469631A1 (en) * | 2010-12-24 | 2012-06-27 | Hitachi Ltd. | Positive electrode active material for secondary battery and magnesium secondary battery using the same |
EP2468693A3 (en) * | 2010-12-24 | 2012-08-22 | Hitachi Ltd. | Thermoelectric Conversion Material |
WO2014013837A1 (ja) * | 2012-07-19 | 2014-01-23 | 株式会社 日立製作所 | リチウムイオン二次電池用活物質粒子およびそれを用いたリチウムイオン二次電池 |
JPWO2013129150A1 (ja) * | 2012-03-01 | 2015-07-30 | 日立金属株式会社 | 電極活物質、この電極活物質を用いた電極及び二次電池 |
WO2019004288A1 (ja) * | 2017-06-30 | 2019-01-03 | 国立大学法人九州大学 | 非水系二次電池用の正極活物質、およびそれを用いた非水系二次電池 |
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CN102318013B (zh) * | 2009-03-27 | 2014-12-03 | 株式会社日立制作所 | 导电性浆料及具备使用其的电极配线的电子部件 |
JP6051514B2 (ja) * | 2010-12-02 | 2016-12-27 | ソニー株式会社 | 固体電解質電池および正極活物質 |
US9337478B2 (en) * | 2012-02-14 | 2016-05-10 | Shailesh Upreti | Composite silicon or composite tin particles |
US10923717B2 (en) | 2016-11-03 | 2021-02-16 | Lg Chem, Ltd. | Lithium ion secondary battery |
JPWO2020066909A1 (ja) * | 2018-09-25 | 2021-08-30 | 東レ株式会社 | 二次電池用電極およびリチウムイオン二次電池 |
CN114420932B (zh) * | 2022-01-05 | 2024-03-01 | 齐鲁工业大学 | 一种高性能含有变价金属离子氧化物微晶玻璃电极材料及制备方法和应用 |
CN114583102B (zh) * | 2022-02-21 | 2023-08-15 | 远景动力技术(江苏)有限公司 | 正极活性材料、电化学装置和电子设备 |
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EP2469631A1 (en) * | 2010-12-24 | 2012-06-27 | Hitachi Ltd. | Positive electrode active material for secondary battery and magnesium secondary battery using the same |
CN102544467A (zh) * | 2010-12-24 | 2012-07-04 | 株式会社日立制作所 | 二次电池用正极活性物质及使用该正极活性物质的镁二次电池 |
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US8802963B2 (en) | 2010-12-24 | 2014-08-12 | Hitachi, Ltd. | Thermoelectric conversion material |
JPWO2013129150A1 (ja) * | 2012-03-01 | 2015-07-30 | 日立金属株式会社 | 電極活物質、この電極活物質を用いた電極及び二次電池 |
WO2014013837A1 (ja) * | 2012-07-19 | 2014-01-23 | 株式会社 日立製作所 | リチウムイオン二次電池用活物質粒子およびそれを用いたリチウムイオン二次電池 |
JP2014022204A (ja) * | 2012-07-19 | 2014-02-03 | Hitachi Ltd | リチウムイオン二次電池用活物質粒子およびそれを用いたリチウムイオン二次電池 |
WO2019004288A1 (ja) * | 2017-06-30 | 2019-01-03 | 国立大学法人九州大学 | 非水系二次電池用の正極活物質、およびそれを用いた非水系二次電池 |
JPWO2019004288A1 (ja) * | 2017-06-30 | 2020-04-23 | 株式会社村田製作所 | 非水系二次電池用の正極活物質、およびそれを用いた非水系二次電池 |
JP7047841B2 (ja) | 2017-06-30 | 2022-04-05 | 株式会社村田製作所 | 非水系二次電池用の正極活物質、およびそれを用いた非水系二次電池 |
US11355752B2 (en) | 2017-06-30 | 2022-06-07 | Murata Manufacturing Co., Ltd. | Positive electrode active substance for non-aqueous secondary battery and non-aqueous secondary battery including the same |
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US20130015410A1 (en) | 2013-01-17 |
JP5759982B2 (ja) | 2015-08-05 |
KR101711525B1 (ko) | 2017-03-02 |
US8951436B2 (en) | 2015-02-10 |
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