WO2004086539A1 - Electrode material for lithium secondary battery and electrode structure having the electrode material - Google Patents
Electrode material for lithium secondary battery and electrode structure having the electrode material Download PDFInfo
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- WO2004086539A1 WO2004086539A1 PCT/JP2004/004071 JP2004004071W WO2004086539A1 WO 2004086539 A1 WO2004086539 A1 WO 2004086539A1 JP 2004004071 W JP2004004071 W JP 2004004071W WO 2004086539 A1 WO2004086539 A1 WO 2004086539A1
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/05—Accumulators with non-aqueous electrolyte
- H01M10/052—Li-accumulators
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M4/00—Electrodes
- H01M4/02—Electrodes composed of, or comprising, active material
- H01M4/36—Selection of substances as active materials, active masses, active liquids
- H01M4/38—Selection of substances as active materials, active masses, active liquids of elements or alloys
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M4/00—Electrodes
- H01M4/02—Electrodes composed of, or comprising, active material
- H01M4/36—Selection of substances as active materials, active masses, active liquids
- H01M4/38—Selection of substances as active materials, active masses, active liquids of elements or alloys
- H01M4/386—Silicon or alloys based on silicon
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/10—Energy storage using batteries
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02T—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
- Y02T10/00—Road transport of goods or passengers
- Y02T10/60—Other road transportation technologies with climate change mitigation effect
- Y02T10/70—Energy storage systems for electromobility, e.g. batteries
Definitions
- the present invention relates to an electrode material for a lithium secondary battery which comprises particles having silicon as a main component , an electrode structure having the electrode material and a secondary battery having the electrode structure.
- lithium ion battery As such a lightweight, compact secondary battery, development of a rocking chair type battery referred to as a "lithium ion battery," which during a charging reaction use a carbonaceous material represented by graphite as a negative electrode substance for allowing lithium ions to intercalate between the planar layers of a 6-membered network- structure formed from carbon atoms, and use a lithium intercalation compound as a positive electrode substance for allowing lithium ions to deintercalate from between layers .
- a carbonaceous material represented by graphite as a negative electrode substance for allowing lithium ions to intercalate between the planar layers of a 6-membered network- structure formed from carbon atoms
- a lithium intercalation compound as a positive electrode substance for allowing lithium ions to deintercalate from between layers .
- the negative electrode formed from a carbonaceous material can theoretically only intercalate a maximum of 1/6 of the lithium atoms per carbon atom, a high energy density secondary battery comparable with a lithium primary battery when using metallic lithium as the negative electrode material has not been realized.
- lithium metal in a dendrite shape develops on the carbon negative electrode surface, possibly ultimately resulting in an internal short-circuit between the negative electrode and positive electrode from the repeated charge/discharge cycles.
- a "lithium ion battery” which has a capacity higher than the theoretical capacity of a graphite negative electrode does not have a sufficient cycle life.
- a high-capacity lithium secondary battery that uses metal lithium for the negative electrode has been drawing attention as a secondary battery having a high energy density but not put in practical use yet.
- This short charge/discharge cycle life is considered to be primarily due to the facts that metal lithium reacts with- impurities such as water or an organic solvent contained in the electrolyte to form an insulating film on the electrodes, and that the foil surface of metallic lithium has an irregular surface wherein portions to which electric field converges exist, so that repeated charging and discharging causes lithium to develop in a dendrite shape, resulting in an internal short-circuit, between the negative and positive electrodes, thereby leading to the end of the battery life.
- lithium alloy is not currently in wide practical use because the lithium alloy is too hard to wind in a spiral form, and therefore a spiral-wound type cylindrical battery cannot be made, because the charge/discharge cycle life is not sufficiently increased, and because a battery using a lithium- alloy for the negative electrode does not have a sufficient energy density comparable to a battery using metal lithium.
- U.S. Patent No. 6, 051, 340 discloses a lithium secondary battery which uses a negative electrode comprising an electrode layer formed of a metal such as silicon or tin alloyed with lithium, and- a metal such as nickel or copper not alloyed with lithium on a current collector of a metal material which does not alloy with lithium.
- U.S. Patent No. 5,795,679 discloses a lithium secondary battery using a negative electrode formed from a metallic powder alloying an element such as tin with an element such as nickel or copper.
- U.S. Patent No. 6,432,585 discloses a lithium secondary battery wherein the electrode material layer contains 35% or more by weight of a powder comprising silicon or tin with a average particle diameter of 0.5 to 60 ⁇ m, and which uses a negative electrode having a porosity ratio of 0.10 to 0.86 and a density of 1.00 to 6.56 g/cm 3 .
- Japanese Patent Application Laid-Open No. Hll- 283627 discloses a lithium secondary battery which uses a negative electrode comprising silicon or tin having an amorphous phase.
- Application Laid-Open No. 2000-311681 discloses a lithium secondary battery which uses a negative electrode comprising particles of an amorphous tin- transition metal element alloy with a substantially non-stoichiometric composition.
- International Publication WO 00/17948 discloses a negative electrode for a lithium secondary battery, comprising particles of an amorphous silicon-transition metal element alloy with a substantially non-stoichiometric composition.
- the electric capacity efficiency resulting from lithium release compared to the electric capacity efficiency resulting from first lithium insertion in the lithium secondary battery according to each of. the proposals does not match the same level of performance as the electrical efficiency of a graphite negative electrode, so that further improvements in efficiency have been awaited.
- resistance of the electrode of the lithium secondary battery of the above proposals is higher than that of a graphite electrode, lowering of the resistance has been desired.
- Japanese Patent Application Laid-Open No. 2000- 215887 discloses a high-capacity high charging/discharging efficiency lithium secondary battery which suppresses volume swelling .when alloying with lithium to prevent break-down of the electrode by increasing conductivity of the electrode by forming a carbon layer the surface of a metal or semi-metal which can alloy with lithium, in particular silicon particles, through chemical vapor disposition with thermal decomposition of benzene and the like.
- a theoretical charge capacity of 4200 mAh/g calculated from Li 4 . 4 Si as the compound of silicon and lithium an electrode performance allowing lithium insertion/release of an electric charge which exceeds 1000 mAh/g has not been reached, making the development of a high-capacity, long life negative electrode desirable.
- the present invention has been accomplished in view of the aforementioned problems, and it is an object of the present invention to provide an electrode material for a lithium secondary battery, having low resistance, high charge/release efficiency and high capacity; an electrode structure having the electrode material; and a secondary battery having the electrode structure.
- the electrode material of the present invention for a lithium secondary battery comprises particles of a solid state silicon alloy having silicon as a main component, wherein the particles of the solid state alloy have a microcrystal or amorphous material comprising an element other than silicon, dispersed in a microcrystalline silicon or amorphized silicon material.
- the solid state alloy preferably contains a pure metal or a solid solution.
- the alloy preferably has an element composition in which the alloy has a single phase in the melted liquid solution state.
- the element composition is a composition in which the alloy is completely mixed in the melted liquid solution, whereby two or more phases are not present in a melted liquid state, which is determined by element species and atomic ratio of elements .
- the electrode material of the present invention for a lithium secondary battery comprises silicon alloy particles or silicon particles having silicon as a main component, wherein the silicon is doped with at least one element selected from the group consisting of boron, aluminum, gallium, antimony and phosphorous, at the dopant amount of an atomic ratio in the range of 1 x 10 "8 to 2 x 10 "1 .
- FIG. 1A and FIG. IB are schematic views of silicon alloy particles according to the present invention.
- FIG. 2A, FIG. 2B and FIG. 2C are views for illustrating a lithium insertion reaction for intrinsic silicon, p-type silicon and n-type silicon;
- FIG. 3A and FIG. 3B are conceptual views schematically illustrating a cross-section of one embodiment of an electrode structure comprising a negative electrode material fine powder for a lithium secondary battery according to the present invention
- FIG. 4 is a conceptual view schematically illustrating a cross-section of one embodiment of a secondary battery (lithium secondary battery) according to the present invention
- FIG. 5 is a cross-sectional view of a single layer, flat type (coin type) battery.
- FIG. 6 is a cross-sectional view of a spiral- wound type cylindrical battery.
- FIGS. 1A to 6 The present invention will hereinafter be explained referring to FIGS. 1A to 6.
- the present inventors investigated the relationship between a silicon dopant and the electric insertion/release charge and insertion/release potential of lithium by conducting the following experiment.
- the reasons for this include:
- a p-type dopant atom such as a boron atom, which substitutes for a silicon atom, is negatively ionized, so that the insertion of lithium ions, which tend to be positively ionized to release an election, is not hindered.
- FIGS. 2A to 2C are views schematically showing the reaction of lithium being electrochemically inserted into silicon crystal, and FIG. 2A shows silicon of an intrinsic semiconductor not containing any impurity atoms . (Actually there would be some impurity atoms contained.)
- FIG. 2B shows a p-type silicon doped with boron as the impurity atom. In this case, it can be expected that an attractive force will exist between the lithium atoms, which tend to form positive ions, and the boron atoms, which tend to form negative ions, whereby it can be guessed that insertion of lithium ions would be easy.
- FIG. 2C shows an n-type silicon doped with phosphorous as the impurity atom. In this case, it can be expected that a repulsion force will exist between the lithium atoms, which tend to form positive ions, and the phosphorous atoms, which tend to form positive ions, whereby it can be guessed that insertion of lithium ions would not be easy.
- the doping amount of the above p-type dopant and n-type dopant is in the range that lowers the resistance of an electrode used in a lithium secondary battery, and increases storage capacity. This range is preferably 1 x 10 ⁇ 8 to 2 x 10 -1 in terms of atomic ratio with respect to silicon, and 1 x 10 ⁇ 5 to 1 x 10 "1 is more preferable.
- To decrease resistance simultaneously doping with both the above p-type dopant and n-type dopant is preferable.
- the above p-type dopant may also include aluminum and gallium, boron having a small ionic radius is more preferable. Further, when doping, the addition of boron in excess of the solid solution threshold is effective in amorphization.
- an electrode having a long cycle life can be prepared when using, as a negative electrode material for a lithium secondary battery, particles or an alloy having boron-doped silicon as a main component.
- the present inventors also investigated the electric charge, charge efficiency and swelling ratio when electrochemical lithium insertion/release is repeated on an electrode using silicon alloy particles as an electrode material. The results showed that nonuniformity in the distribution of elements within the alloy particles was low and that smaller silicon crystalline particles obtain a higher lithium insertion/release electric charge. The results also showed that it is possible to carry out repeated lithium insertion/release with stability and that an electrode with a low swelling ratio can be prepared.
- a preferable embodiment of the present invention directed to making the distribution of elements within the alloy particles more uniform, and to making the size of the silicon, crystallite particles smaller was carried out.
- This embodiment showed that it is effective to prepare the element composition of the silicon alloy such that: (1) Silicon and elements other than silicon which constitute the silicon alloy are in a melted solution state to provide a uniform solution. (2)
- the silicon alloy contains a eutectic, (this eutectic may contain a eutectic of silicon and a first element A described below, silicon and a second element E described below, first element A and second element E and combinations thereof)
- the intermetallic compound formed between silicon and elements other than silicon which constitutes the silicon alloy is not readily crystalized.
- the alloy particles comprising the electrode material of the present invention preferably include a pure metal or a solid solution, because it is thought that a pure metal or solid solution is superior to intermetallic compounds regarding lithium insertion/release. This is, of course, not to deny the presence of silicon intermetallic compounds in the alloy metal, but the ratio of silicon intermetallic compounds is preferably 0 or at a very low level.
- Preferable alloy particles used in the present invention may be a pure metal and a solid state coexisting, or may be either or both of a pure metal and a solid state coexisting with an intermetallic compound.
- the ratio of silicon contained in the above silicon alloy is, in order to express high storage performance, preferably 50 % by weight or more and 95 % by weight or less, and more preferably 50 % by weight or more and 90 % by weight or less.
- atomizing or pulverizing the silicon alloy particles to an average particle diameter preferably in the range of 0.02 ⁇ m to 5 ⁇ , more preferably 0.05 ⁇ m to 3 ⁇ m and most preferably 0.1 ⁇ m to 1 ⁇ m, as well as amorphization of the silicon alloy, are effective to obtain the desired performance.
- amorphization means a structure which comprises an amorphous phase, wherein sections where stripes were not observed were confirmed to exist by observation of the crystal lattice image with a high resolution transmission electron microscope.
- the crystallite size of the amorphized particles in the silicon alloy particles observed from the transmission electron microscope is preferably in the range of 1 nm to 100 nm, and more preferably in the range of 5 nm to 50 nm.
- the pulverized fine powder is an agglomeration of "fine particles".
- silicon can electrochemically release and receive a large amount of lithium, by making the silicon crystallite small, the lithium insertion/release reaction can be made uniform. This, in turn, allows the volume swelling and contraction due to the repeated insertion/release to be made uniform, thereby lengthening the cycle life.
- FIGS. 1A and IB are cross-sectional views schematically showing the silicon alloy particles of the present invention finely pulverized or amorphized.
- reference numeral 100 denotes a silicon alloy particle
- reference numeral 101 denotes a group of silicon crystals microcrystallized or amorphized
- reference numeral 102 denotes a group of crystals of a first element (other than silicon) contained in the silicon alloy microcrystallized or amorphized
- reference numeral 103 denotes a group of crystals microcrystallized or amorphized of a second element (other than silicon) contained in the silicon alloy.
- the silicon alloy particles 100 of FIG. 1A are alloy particles which comprise at least a silicon element and a first element
- the silicon alloy particles 100 of FIG. IB are alloy particles which comprise at least a silicon element, a first element and a second element.
- a uniformly melted solution can be solidified to form the silicon alloy of the element composition in the manner of the above-mentioned (1) .
- the difference in melting points between silicon and the first element, which next silicon is the main component of the silicon alloy is large, for example, when the first element is tin, even if the melted liquid is rapidly cooled, the segregation of lower melting point tin separates is generated at the particle boundaries of silicon. For that reason, a uniform alloy composition cannot be obtained for an alloy of silicon and tin.
- an alloy obtained by the rapid cooling of a liquid melted from the alloy composition materials is pulverized into a fine powder, then by a method of mechanical alloying using a grinder such as ball mill, the alloy composition is simultaneously made uniform (uniform dispersion of the component elements within the alloy) and amorphized.
- a grinder such as ball mill
- the silicon alloy particles 100 of one preferable embodiment of the present invention when used as the negative electrode material of a lithium secondary battery, can make lithium insertion during charging more uniform, and swelling more uniform when the lithium is inserted, thereby reducing swelling volume.
- the production of a lithium secondary battery having increased storage capacity, improved charging/discharging efficiency and long charge/discharge cycle life can be achieved.
- the microstructure of the silicon alloy particles 100 of the present invention can be observed by selected-area electron diffraction analysis using a transmission electron microscope.
- the degree of microcrystallization or amorphization can be evaluated by calculating the X-ray diffraction peak half width values. If the ratio of the amorphous phase becomes larger, the peak half value width of the X-ray diffraction chart peak widens and the peak becomes broader although the peak is sharp for crystalline phase. It may noted that the half value width for the diffraction intensity at 2 ⁇ of the main peak of the X-ray diffraction chart peak is preferably 0.1° or more, and more preferably 0.2° or more.
- the crystallite size calculated from the X-ray diffraction peak half width values is preferably 60 nm or less, and more preferably 30 nm or less.
- boron at the solid solution threshold or more, or yttrium or zirconium.
- the amount of boron added is preferably in the range of 0.1 to 5% by weight.
- the amount added of the yttrium or zirconium is preferably in the range of 0.1 to 1% by weight.
- Microcrystallization or amorphization of the crystal also allows the crystal structure to lose its long distance orderliness. This means that the degree of freedom increases thus reducing deformation in the crystal structure during lithium insertion. As a result, swelling during lithium insertion is also reduced. In addition, the amorphization of silicon is further promoted by the repeated insertion/release of lithium.
- the silicon alloy particles according to the present invention are employed as a negative electrode for a lithium secondary battery, a secondary battery which has high charging/discharging efficiency, high capacity and a long charge/discharge cycle life can be obtained.
- the reason for the longer cycle life is thought to be that deformation in the crystal structure due to repeated lithium insertion/release is small.
- the first element A is preferably at least one element selected from the group consisting of tin, indium, gallium, copper, aluminum, silver, zinc, titanium and germanium. If the first element is selected from the group consisting of tin, indium, gallium, aluminum, zinc, silver and germanium, which can electrochemically insert and release lithium, it has the same effect as of silicon crystalline particles mentioned above, whereby a high performance material can be obtained for a negative electrode for a lithium secondary battery.
- germanium is expensive and therefore is not suitable from the standpoint of providing a low cost electrode material
- the elements are respectively uniform in a melted liquid solution state, but do not mutually soluted in a solid state.
- a eutectic of Si and Ag crystallizes.
- the melted liquid state is uniform, causing a partial solid solution, whereby a eutectic of Si and Si-Al solid solution crystallizes.
- silicon is preferably 67 atomic% or above, wherein in this range the melted liquid state is uniform. Further, silicon at 85 atomic% or above is more preferable. In this case generation of T.iSi 2 intermetallic compounds is low, and a eutectic of Si and TiSi 2 crystallizes. For that reason, for an alloy formed from silicon and titanium, the composition preferably has the ratio of silicon atoms to titanium atoms close to 85:15. However, from the standpoint of increasing storage performance, the silicon ratio is preferably higher.
- the melted liquid state is uniform, wherein the generation of Cu 3 Si intermetallic compounds is low, and a eutectic of Si and Cu 3 Si crystallizes.
- the above eutectics are effective in that the crystallite in the alloy can be made small. Compositions close to the eutectic point are also more easily amorphized.
- the above silicon alloy comprises silicon, a first element A, and a second element E, wherein the first element A has a lower atomic ratio than silicon, but has the next highest atomic ratio, and the second element E has the next h-ighest atomic ratio after the first element A (refer to FIG. IB), it is preferable that the first element A' is at least one element selected from the group consisting of tin, aluminum and zinc, and the second element E at least one element selected from the group consisting of copper, silver, zinc, titanium, aluminum, vanadium, yttrium, zirconium and boron (the first element A and the second element E are different elements) .
- this second element E is that it crystallizes a eutectic with the first element A and makes the crystallite of first element A smaller, or crystallizes a eutectic with silicon and makes the crystallite of silicon smaller. Further, the second element E forms an oxide more easily than silicon, making it effective in suppressing the generation of a silicon oxide. If a large amount of silicon oxides exist in the silicon or silicon alloy, lithium oxide forms from the electrochemical lithium insertion reaction,, which is a factor in lowering the efficiency of the amount of lithium released (discharged) with respect to the amount of lithium inserted.
- silicon alloy comprising three or more elements include alloys such as Si-Sn-Ti alloy, Si- Sn-Al alloy, Si-Sn-Zn alloy, Si-Sn-Ag alloy, Si-Sn-B alloy, Si-Sn-Sb-B alloy, Si-Sn-Cu-B alloy, Si-Sn-Cu- Sb-B alloy, Si-Al-Cu alloy, Si-Al-Ti alloy, Si-Al-Zn alloy, Si-Al-Ag alloy, Si-Zn-Ti alloy, Si-Zn-Sn alloy, Si-Zn-Al alloy, Si-Zn-Ag alloy, Si-Zn-Cu alloy, Si- Sn-Al-Ti alloy, Si-Sn-Zn-Ti alloy and Si-Sn-Ag-Ti alloy.
- Sn, Zn, Al and Ag crystal particles become smaller by eutectic crystallizing.
- silicon alloy it is preferable to retain a silicon ratio which can maintain capacity as a negative electrode material for a lithium secondary battery, and therefore preferable to select a composition in which elements other than silicon crystallize.
- silicon alloys comprising three or more elements, if the alloy comprises tin, aluminum, zinc, or silver, which can electrochemically insert/release lithium, it is preferable to select a composition close to the eutectic point so that the crystals become microcrystalline or amorphous .
- the dope with at least one p-type dopant selected from the group consisting of boron, aluminum, gallium, antimony and phosphorous having an atomic ratio in the range of 1 x 10 "8 to 2 x 10 "1 with respect to silicon to lower electrical resistance and increase capacity, while doping in the range of 1 x 10 ⁇ 5 to 1 x 10 -1 is more preferable.
- the dopant is still more preferably, boron, which is a p-type dopant having a small ionic radius .
- an additional effect is that during the preparation process of the silicon alloy, or the pulverizing process, oxygen reacting with silicon to form silicon oxide can be suppressed. This is because the aluminum atom, or titanium, vanadium, yttrium or zirconium atom form a more stable bond with the oxygen atom than silicon. Note that if silicon oxide forms, the efficiency of the electrochemical insertion/release of lithium decreases. This is thought that lithium reacts with the silicon oxide to form inert lithium oxide . .
- the average particle diameter of primary particles of the above silicon or silicon alloy of the present invention is, as a negative electrode material for a lithium secondary battery, preferably in the range of 0.02 to 5.0 ⁇ m, and more preferably in the range of 0.05 to 3.0 ⁇ m, so that the electrochemical insertion/release of lithium occurs uniformly and rapidly.
- silicon particles having silicon as a main component or silicon alloy particles having silicon as a main component, complexing with a carbonaceous material or metal magnesium or a carbonaceous material and metal magnesium, can increase performance relating to battery charging/discharging efficiency, battery voltage, release current characteristics, repeated charge/discharge characteristics and the like, if such complexed material is used as the negative electrode for a lithium secondary battery.
- the complexing of a carbonaceous material can lower fatigue caused by volume swelling and contraction during repeated electrochemical lithium insertion/release (discharge), thereby extending life
- the amount to be added to the alloy having silicon as a main component is preferably 1 to 10% by weight, and more preferably 2 to 5% by weight, where the amount of lithium insertion/release (discharge) does not remarkably decrease.
- Complexing with magnesium metal is effective in increasing battery voltage if the complex is used to form a- lithium secondary battery. If the ratio of complexed magnesium metal is increased, battery voltage increases. However, in such a case because the ratio of silicon decreases, the storable electric capacity decreases.
- the surface is preferable to cover the surface with a thin oxide of about 2 to 10 nm.
- the oxide film thickness can be measured by analyzing the depth profile of the oxygen element with a surface analyzer such as that of scanning micro-auger analysis.
- average particle diameter means the average primary particle diameter (average particle diameter in a non- clustered state) .
- microcrystallized or amorphized silicon or silicon alloy particles according to the present invention in addition to the above X-ray diffraction analysis, may also be evaluated by electron diffraction, neutron diffraction, high resolution electron microscope observation and the like.
- evaluation will yield a halo shape diffraction chart.
- evaluation will provide a microcrystalline structure in which a striped lattice image is observed (a stripe pattern is interspersed) showing fine defined regions, or a maze-like pattern of an amorphized structure which does not show lattice striping may be observed.
- EXAFS extended X-ray absorption fine structure
- XAFS analysis of X-ray absorption fine structure
- the crystallite size of the particles can be determined using the following Scherrer formula from the diffraction angle and half value width of an X-ray diffraction curve using CuK ⁇ at the radiation source.
- Lc 0.94 ⁇ / ( ⁇ cos ⁇ ) (Scherrer' s Formula) Lc: crystallite size ⁇ : wavelength of X-ray beam ⁇ : half width value of an X-ray diffraction peak (radian) ⁇ : Bragg angle of the diffraction line
- the crystallite size obtained by the above formula becomes smaller as amorphization progresses.
- the crystallite size of the electrode material according to the present invention calculated from the above formula is preferably 60 nm or less, and more preferably 30 nm or less.
- the silicon particles having silicon as a main component according to the present invention are prepared by mixing specific amounts of the silicon basic ingredient and doping element material, then melting and cooling to form a silicon ingot.
- the ingot is then pulverized in a multistage process to give a fine powder having an average particle diameter of 0.1 to 1.0 ⁇ m.
- Apparatuses which can be used for the pulverizing process include a ball-type mill such as a planetary-type ball mill, an vibration ball mill, a conical mill and a tube mill; a media type mill such as an agitating grinder type, a sand grinder type, an anealer type and a tower type.
- the ball material for the above grinding media is preferably zirconia, stainless steel or steel.
- the dopant is preferably boron, antimony, or phosphorous, and more preferable is boron.
- the silicon alloy particles according to the present invention are prepared by mixing specific amounts of a metal material of a first element, if desired a metal material of a second element and a doping element material to a basic ingredient of silicon, which mixture is melted to form a molten metal, then cooled to prepare powder shaped silicon alloy particles.
- a metal material of a first element if desired a metal material of a second element and a doping element material to a basic ingredient of silicon, which mixture is melted to form a molten metal, then cooled to prepare powder shaped silicon alloy particles.
- atomization method methods such as gas atomization for atomizing with a high- pressure inert gas, water atomization for atomizing with high-pressure water and the like can be used.
- Cooling of the above molten metal is preferably performed rapidly. This is because the molten metal state as described above is in a uniformly dissolved state, whereby rapidly cooling the molten metal will give a more uniform composition for the silicon alloy which comprises elements having different melting points.
- the speed of such cooling is preferably within the range of 10 3 to 10 8 K/s.
- a fine powder can be obtained through a multi-stage pulverization process preferably having an average particle diameter of 0.02 ⁇ m to 5.0 ⁇ m, more preferably 0.05 ⁇ m to 3.0 ⁇ m and still more preferably 0.1 ⁇ m to 1.0 ⁇ m. Further, by planetary- type ball mill treatment and the like, amorphization can be achieved. An vibration mill, a planetary-type ball mill, a high-speed rotation mill and the like are preferable as the pulverizing apparatus for amorphization.
- More preferable methods include atomization methods such as a method of mixing materials to become the ingredients, melting them to form a molten metal, then injecting the molten materials with inert gas to form a powder (so-called gas atomization method) ; a method of forming a powder by blowing the molten materials onto a rotating disk or injects the molten materials with highly pressurized water (so- called water atomization) ; and a method of pouring a sprayed metal into a high-revolution water stream (spraying method) .
- atomization methods such as a method of mixing materials to become the ingredients, melting them to form a molten metal, then injecting the molten materials with inert gas to form a powder (so-called gas atomization method) ; a method of forming a powder by blowing the molten materials onto a rotating disk or injects the molten materials with highly pressurized water (so- called water atomization) ; and
- the particle powder After once the particle powder is formed, it is further pulverized to obtain a silicon powder or silicon alloy powder having an average particle diameter of preferably 0.02 ⁇ m to 5.0 ⁇ m, more preferably 0.05 ⁇ m to 3.0 ⁇ m and still more preferably 0.1 ⁇ m to 1.0 ⁇ m.
- element composition within the injected alloy particles can be made even more uniform by subjecting it to ultrasonic waves. Further, by increasing the cooling speed in the above atomization method, amorphization can be performed more easily.
- the powder can be treated with an amorphization pulverizer such as a ball mill to make the distribution of the elements in the alloy more even, and to promote amorphization of the alloy.
- a silicon powder or silicon alloy powder can be obtained by rapidly cooling with a gun method, a single roll method or a double roll method, then pulverizing the obtained powder or ribbon.
- the preferable average thickness of the present invention is 0.02 ⁇ m to 5.0 ⁇ m, more preferably 0.05 ⁇ m to 3.0 ⁇ m and still more preferably 0.1 ⁇ m to 1.0 ⁇ m.
- the obtained powder can be further amorphized by treating with a ball mill and the like.
- An amorphized fine powder having a particle diameter of 10 to 100 nm can be obtained by supplying the ingredients of the present invention, silicon powder or silicon alloy powder, as material for evaporation in a plasma gas energized with high frequency waves in an inert gas .
- the plasma can be made more stable and the fine powder can be obtained more efficiently by applying a magnetic field when energizing with the high frequency waves.
- It is preferable to cover the surface of the fine powder with an oxide-film or carbon-film as the above silicon powder or silicon alloy powder is vulnerable to oxidation in air and can easily dissolve in aqueous alkaline solution.
- a thin ⁇ xide- film can be formed on the surface of the fine powder by carrying out the micro-pulverization process in a solution such as alcohol.
- a thin oxide-film can be also formed on the surface of the fine powder by exposing the fine powder to an inert gas atmosphere such as nitrogen gas or argon gas containing a low concentration of oxygen gas prior to pulverizing. .
- the oxygen concentration in the nitrogen gas or inert gas is preferably in the range of 0.01 to 5.0 volume!, and more preferably in the range of 0.05 to 2.0 volume%.
- the weight percentage of oxygen in the fine powder having a thin oxide-film formed on its surface is preferably in the range of 0.1 to 15% by weight, and more preferably in the range of 0.2 to 1 . 0% by weight, and still more preferably in the range of 0.2 to 5% by weight.
- a high discharge amount and high charging/discharging efficiency cannot be achieved when, the silicon powder or silicon alloy powder of the present invention containing a high oxygen or oxide weight is used as an electrode material, for a lithium secondary battery. This is because the lithium reacts with the oxide during lithium insertion, changing to an inert substance such as lithium oxide, thus preventing electrochemical discharge. Unless the amount of oxygen, in other words the amount of oxide, is sufficient to become an oxidation preventing film covering the surface of the silicon powder or silicon alloy powder of the present invention, the present powders will easily oxidize in air to form an inert product in the charge/discharge reaction of the slurry battery.
- the above carbon-film for preventing oxidation may be formed by mixing a fine powder carbon content such as graphite powder or acetylene black when pulverizing or amorphizing the silicon or silicon powder .
- the silicon fine particles or silicon alloy fine particles of the present invention can be formed by a method such as sputtering, electron beam deposition, and cluster ion beam deposition.
- FIGS. 3A and 3B illustrate schematically sections of the electrode structure according to the present invention.
- reference numeral 302 represents an electrode structure, wherein this electrode structure 302 comprises an electrode material layer 301 and a current collector 300.
- This electrode material layer 301 comprises, as illustrated in FIG. 2B or FIG. 1A or FIG.
- IB particles (active material) 303 having silicon, as a main component (silicon Si or silicon alloy powder), a conductive auxiliary material 304 and a binder 305. While in FIGS. 3A and 3B the electrode material layer 301 is provided only on one surface of the current collector 300, depending on the battery configuration, an electrode material layer may be formed on both sides of the current collector 300.
- the content of conductive auxiliary material 304 is preferably 5% or more by weight and 40% or less by weight, and more preferably 10% or more by weight and 30% or less by weight.
- the content of binder 305 is preferably 2% or more by weight and 20% or less by weight, and more preferably 5% or more by weight and 15% or less by weight.
- the content of particles 303 having silicon as a main component contained in the electrode material 301 is preferably within the range of 40% by weight to 93% by weight.
- the conductive auxiliary material 304 includes graphite structure carbonaceous materials, such as graphite, carbon fiber and carbon nanotubes; and amorphous carbons such as acetylene black and ketjen black; nickel, copper, silver, titanium, platinum, aluminum, cobalt, iron, chrome and the like, although graphite is preferable.
- the shape of the conductive auxiliary material is preferably a shape selected from shapes such as spherical, flake-shaped, filament-shaped, fiber-shaped, spike-shaped and needle-shaped. In addition, by employing two or more different shapes in the powder, packing density when forming the electrode material layer can be increased thus reducing impedance of the electrode structure 302.
- the material for the binder 305 may include a water soluble polymer such as polyvinyl alcohol, water soluble ethylene-vinyl alcohol polymer, polyvinyl butyral, polyethylene glycol, sodium carboxymethyl cellulose and hydroxyethyl cellulose; a fluorocarbon resin such as polyvinylidene fluoride and vinylidene fluoride-hexafluoropropylene copolymer; a polyolefin such as polyethylene and polypropylene; styrene-butadiene rubber, polyimide, polyamic acid (polyimide precursor) and polyamide- i ide. Materials having a tensile strength of 100 to 400 MPa, stretch ratio of 40 to 100% are preferable as the binder, and polyimide, polyamic acid (polyimide precursor) and polyamide-imide are more preferable .
- a water soluble polymer such as polyvinyl alcohol, water soluble ethylene-vinyl alcohol polymer, polyvinyl
- the electrode it is preferable when forming the electrode to complex the binder by adding a polymer which can absorb the solvent of the electrolyte solution by gelling, such as polyacrylonitrile or polymethylmethacrylate. This improves permeation and decreases the resistance of the electrode.
- a polymer which can absorb the solvent of the electrolyte solution by gelling such as polyacrylonitrile or polymethylmethacrylate. This improves permeation and decreases the resistance of the electrode.
- the material forming the current collector 300 prefferably has high electric conductance, and be an inert material in battery reactions, in particular when applying an electrode structure 302 to the negative electrode of a secondary battery. This is because the current collector 300 is designed for efficiently supplying the current to be consumed by the electrode reaction when charging, or collecting the electric current generated when discharging.
- Preferable materials include at least one metallic material selected from the group consisting of copper, nickel, iron, stainless steel, titanium and platinum. More preferable materials include copper, which is low in cost and has low electrical resistance.
- the shape of the current collector is a sheet shape
- this "sheet shape” is, within the scope of practical use, not particularly limited in thickness, wherein thickness may be about 100 ⁇ m or less, and includes a so-called “foil” shape.
- a sheet shape used, for example, in making a mesh shape, sponge shape and a fiber shape, or punching metal, expanded metal can be employed.
- a binder 305 and a conductive auxiliary material were mixed with the silicon powder or silicon alloy powder composed of particles having silicon as a main component according to the present invention, to which an appropriate solvent for the binder 305 was added and kneaded to prepare a slurry.
- the prepared slurry was applied to a current collector 300, dried and after forming an electrode material layer 301, was subjected to press processing, wherein the thickness and density of the electrode material layer 301 was adjusted to form an electrode structure 302.
- a coater coating method for example, or a screen printing method can be used for the above application method.
- the main component can be mixed with the conductive auxiliary material 304 and binder 305, without adding a solvent, and the conductive auxiliary material 304 alone may be pressure formed with the above negative electrode material, without mixing with the binder 305, to form an electrode material layer 301. If the electrode material layer 301 density is too high, swelling when lithium is inserted becomes large, thereby causing peeling off from the current collector 300 to occur. If the electrode material layer 301 density is too low electrode resistance becomes high, thereby leading to a lowering in charging/discharging efficiency and a large drop in voltage of the battery when discharging. For these reasons, the density, of the electrode material layer 301 according to the present invention is preferably within a range of 0.8 to 2.0 g/cm 3 , and more preferably within a range of 0.9 to 1.5 g/cm 3 .
- An electrode structure 302 formed from only the silicon particles or silicon alloy particles of the present invention, without using the above conductive auxiliary material 304 or binder 305, can also be prepared by forming a direct electrode material layer 301 to the current collector 300 using a method such as sputtering, electron beam deposition, and cluster ion beam deposition.
- a method such as sputtering, electron beam deposition, and cluster ion beam deposition.
- the thickness of the electrode material layer 301 is made thick, peeling tends to occur at the interface with the current collector 300, and therefore the above deposition methods are not suitable for forming a thick electrode structure 102.
- a metal layer or an oxide layer or a nitride layer is preferably provided in a thickness of 1 to 10 nm to the current collector 300 thereby forming concave and convex surfaces on the current collector 300 to improve interface adhesion.
- a more specific oxide layer or nitride layer preferably includes silicon or a metal oxide layer or nitride layer.
- the secondary battery according to the present invention comprises an electrolyte, a positive electrode and a negative electrode used in an electrode structure having the above characteristics, and uses a lithium oxidation reaction and a lithium ion reduction reaction.
- FIG. 4 is a view illustrating such a general structure of a lithium secondary battery according to the present invention, in which reference numeral 401 represents a negative electrode using an electrode structure of the present invention, reference numeral 402 an ionic conductor, reference numeral 403 a positive electrode, reference numeral 404 a negative electrode terminal, reference numeral 405 a positive electrode terminal and reference numeral 406 a battery case (housing) .
- the above secondary battery was assembled by sandwiching and laminating the ionic conductor 402 between the negative electrode 401 and the positive electrode 403 to form stacked electrodes, then after this stacked electrodes had been inserted into the battery case in dry air or a dry inert gas atmosphere in which the dew point was sufficiently controlled, respective electrodes 401, 403 were connected with the respective electrode terminals 404, 405, and the battery case sealed.
- the battery When using a material which retains the electrolyte on a micro-porous plastic film as the ionic conductor 402, the battery is assembled by forming the electrode bank so as to sandwich a micro- porous plastic film between the negative electrode 401 and the positive electrode 403 as a separator to prevent short-circuiting, then connecting the respective electrodes 401, 403 with the respective electrode terminals 404, 405 and sealing the battery case .
- the lithium secondary battery which uses an electrode structure comprising an electrode material of the present invention on the negative electrode has high charging/discharging efficiency and capacity and high energy density in accordance with the advantageous effects of the above negative electrode.
- the positive electrode 403 which is the counter electrode of the lithium secondary battery using the electrode structure of the present invention on the negative electrode, is at least a source of lithium ions, comprising a positive electrode material serving as a lithium ion host material, and preferably comprises a current collector and a layer which is formed from a positive electrode material serving as a lithium ion host material.
- the layer formed from such a positive electrode material is, more preferably, a binder and a positive electrode material serving as a lithium ion host material, and may sometimes comprise a material to which a conductive auxiliary material has been added.
- the positive electrode material serving as a host which is a source of lithium ions used in the lithium secondary battery of the present invention is preferably a lithium-transition metal (complex) oxide, lithium-transition metal (complex) sulfide, lithium- transition metal (complex) nitride or lithium- transition metal (complex) phosphate.
- the transition metal for the above transition metal oxide, transition metal sulfide, transition metal nitride or transition metal phosphate includes, for example, metal elements having a d-shell or an f-shell, i.e., Sc, Y, lanthanoids, actinoid, Ti, Zr, Hf, V, Nb, Ta, Cr, Mo, W, Mn, Tc, Re, Fe, Ru, Os, Co, Rh, Ir, Ni, Pb, Pt, Cu, Ag, and Au, and in particular Co, Ni, Mn, Fe, Cr, and Ti are preferable.
- metal elements having a d-shell or an f-shell i.e., Sc, Y, lanthanoids, actinoid, Ti, Zr, Hf, V, Nb, Ta, Cr, Mo, W, Mn, Tc, Re, Fe, Ru, Os, Co, Rh, Ir, Ni, Pb, Pt, Cu, Ag, and Au, and in particular Co, Ni,
- the crystal grains can be made finer and insertion/release a larger amount of lithium can be performed with stability by incorporating 0.001 to 0.01 parts of yttrium (Y) element, or elements of Y and zirconium (Zr) to 1.0 parts of lithium to the lithium-transition metal
- lithium-transition metal (complex) oxide lithium-transition metal (complex) sulfide, lithium-transition metal (complex) nitride or lithium-transition metal (complex) phosphate, in particular the lithium-transition metal (complex) oxide.
- the positive electrode active material is a powder
- the positive electrode is made by using a binder, or made by forming the positive electrode active material layer on the current collector by sintering or depositing. Further, where the powder of the positive electrode active material has low conductivity, similar to the formation of the active material layer for the above electrode structure, mixing in an appropriate conductive auxiliary material is required.
- the conductive auxiliary materials and binders that may be used are the same as those which were mentioned above for the electrode structure 302 of the present invention.
- the current collector material used for the above positive electrode is preferably a material such as aluminum, titanium, nickel and platinum which have high electrical conductivity, and, are inert in the battery reaction.
- nickel, stainless steel, titanium and aluminum are preferable, of those aluminum is more preferable because it is low cost and has high electrical conductivity.
- shape of the current collector is a sheet shape
- this "sheet shape” is, within the scope of practical use, not particularly limited in thickness, wherein thickness may be about 100 ⁇ m or less, and encompasses a so-called “foil” shape.
- the sheet shape used for example, in making a mesh shape, sponge shape and a fiber shape, or punching metal, and expanded metal can be employed.
- lithium ion conductors such as a separator. having an electrolyte solution (the electrolyte solution prepared by dissolving an electrolyte in a solvent) retained therein, a solid electrolyte, or a solidified electrolyte obtained by gelling an electrolyte solution with a polymer gel and a complex of a polymer gel and a solid electrolyte can be used.
- the conductivity of the ionic conductor 402 at 25°C is preferably 1 x 10 "3 S/cm or more, and more preferably 5 x 10 ⁇ 3 S/cm or more.
- the electrolyte can include salts such as LiBF 4 , LiPF 6 , LiAsF 6 , LiCl0 4 , LiCF 3 S0 3 , LiBPh 4 , LiSbF 6 , LiC 4 F 9 S0 3 , Li(CF 3 S0 2 ) 2 N and Li(CF 3 S0 2 ) 3 C of lithium ions (Li + ) with a Lewis acid ion (BF 4 ⁇ , PF 6 ⁇ , AsF 6 ⁇ , C10 4 ⁇ , CF 3 S0 3 ⁇ , or BPh 4 ⁇ (with Ph being a phenyl group) and mixtures thereof. It is desirable if the above salts are subjected to sufficient dehydration and deoxygenation by heating under low pressure.
- salts such as LiBF 4 , LiPF 6 , LiAsF 6 , LiCl0 4 , LiCF 3 S0 3 , LiBPh 4 , LiSbF 6 , LiC 4 F 9
- the solvent for the electrolyte includes, for example, acetonitrile, benzonitrile, propylene carbonate, ethylene carbonate, dimethyl carbonate, diethyl carbonate, ethylmethyl carbonate, dimethyl formamide, tetrahydrofuran, nitrobenzene, dichloroethane, diethoxyethane, 1, 2-dimethoxyethane, chlorobenzene, ⁇ -butyrolactone, dioxolane, sulfolane, nitromethane, dimethyl sulfide, dimethyl sulfoxide, methyl formate, 3-methyl-2-oxazolidinone, 2- methyltetrahydrofulan, 3-propylsydnone, sulfur dioxide, phosphoryl chloride, thionyl chloride, sulfuryl chloride or a liquid mixture thereof.
- the above electrolyte solvent is preferably a combination of ethylene carbonate, ⁇ -butyrolactone and diethyl carbonate
- the solid electrolyte can include a glass material such as an oxide material comprising lithium, silicon, phosphorus, and oxygen elements, a polymer chelate of an organic polymer having an ether structure.
- the solidified electrolyte is preferably obtained by gelling the above electrolyte solution with a gelling agent to solidify the electrolyte solution.
- the gelling agent a polymer which can absorb the solvent of the electrolyte solution by swelling, or a porous material such as silica gel, capable of absorbing a large amount of liquid.
- the polymer can include polyethylene oxide, polyvinyl alcohol, polyacrylonitrile, polymethylmethacrylate, and vinylidenefluoride-hexafluoropropylene copolymer.
- the ionic conductor 402 comprising the separator which carries out the role of prevention short- circuiting of the negative electrode 401 and the positive electrode 403 in the secondary battery, because on occasion it has a role in retaining the electrolyte solution, is required to have a plurality of fine pores through which lithium ions can pass, and be stable and insoluble in the electrolyte solution.
- the ionic conductor 402 (separator) preferably comprises, for example, a micropore structure made of glass, a polyolefin such as polypropylene or polyethylene or a fluororesin and the like; or a nonwoven fabric.
- the ionic conductor may comprise a metal oxide film having a plurality of micropores or a resin film complexed with the metal oxide.
- the specific shape of the secondary battery according to the present invention may be, for example, a flat shape, a cylindrical shape, a rectangular parallelepiped shape, a sheet shape or the like.
- the structure of the battery may be, for example, a single layer type, a multiple layer type, a spiral type or the like.
- a spiral type cylindrical battery permits an enlarged electrode surface area by rolling a separator which is sandwiched between a negative electrode and a positive electrode, thereby being capable of supplying a high current during charge/discharge.
- batteries having a rectangular parallelepiped shape or sheet shape permit effective utilization of accommodation space in appliances that will be configured by accommodating a plurality of batteries therein.
- FIG. 5 is a sectional view of a single layer type flat battery (a coin type) and FIG. 6 is a sectional view of a spiral type cylindrical battery.
- These lithium secondary batteries generally comprise the same structure as that illustrated in FIG. 4, a negative electrode, a positive electrode, an electrolyte, an ionic conductor, a battery housing and an output terminal.
- reference numerals 501 and 603 represent negative electrodes
- reference numerals 503 and 606 represent positive electrodes
- reference numerals 504 and 608 represent a negative electrode cap and a negative electrode can, respectively, as the negative electrode terminal
- reference numerals 505 and 609 represent a positive electrode can and a positive electrode cap, respectively, as the positive electrode terminal
- reference numeral 502 and 607 represent ionic conductors
- reference numerals 506 and 610 represent gaskets
- reference numeral 601 represents a negative electrode current collector
- reference numeral 604 represents a positive electrode current collector
- reference numeral 611 represents an insulating sheet
- reference numeral 612 represents a negative electrode lead
- reference numeral 613 represents a positive electrode lead
- reference numeral 614 represents a safety valve.
- the positive electrode 503 that contains a positive electrode material layer and the negative electrode 501 that contains a negative electrode material layer are laminated with an ionic conductor 502 which is formed by a separator that retains at least an electrolyte solution therein, wherein the stack is accommodated from a side of the positive electrode into the positive electrode can 505 used as a positive terminal and the negative electrode is covered with the negative electrode cap 504 used as a negative electrode.
- a gasket 506 is provided in the remaining portions of the positive electrode can.
- the positive electrode 606 having a positive electrode (material) layer 605 formed on the positive electrode current collector 604 is opposed to a negative electrode 603 having the negative electrode (material) layer 602 formed on the negative electrode current collector 601 via the ionic conductor 607 which is formed by a separator that retains at least an electrolyte solution therein so as to compose a cylindrical stack rolled up multiple times .
- the cylindrical stack is accommodated in the positive electrode can 608 used as a positive electrode terminal. Furthermore, the positive electrode cap 609 is disposed as a positive electrode terminal on a side of an opening of the negative electrode can 608 and a gasket 610 is disposed in the remaining parts of the negative electrode can. The cylindrical electrode stack is separated from a side of a positive electrode cap by the insulating sheet 611.
- the positive electrode 606 is connected to the positive electrode cap 609 by way of the positive electrode lead 613.
- the negative electrode 603 is connected to the negative electrode can 608 by way of the negative electrode lead 612.
- the safety valve 614 is disposed on the side of the positive electrode cap to adjust internal pressure of the battery.
- the active material layer 602 of the negative electrode 603 use a layer comprising the above negative electrode material fine powder of the present invention.
- Ionic conductors 502, 607 as separators are sandwiched between the negative electrodes 501, 603, and the formed positive electrodes 503, 606, and assembled into the positive electrode can 505 or negative electrode can 608.
- the negative electrode cap 504 or the positive electrode cap 609 is assembled with the gasket 506, 610.
- the assembly obtained in (2) above is caulked.
- the battery is completed in this way. Note that the above-described preparation of the materials for the lithium battery and assembly of the battery is desirably carried out in dry air from which water has been removed sufficiently or in a dry inert gas.
- the gaskets 506, 610 may comprise, for example, a fluororesin, a polyolefin resin, a polyamide resin, a polysulfone resin, or a rubber material.
- the sealing of the battery may be conducted by way of glass-sealing, sealing using an adhesive, welding or soldering, besides the caulking using the insulating packing shown in FIG. 5 and FIG. 6.
- the insulating plate 611 shown in FIG. 6 may comprise a material selected from organic resin materials and ceramics
- the battery housing comprises the positive electrode can or the negative electrode can 505, 608, and the negative electrode cap or the positive electrode cap 504, 609.
- Such a battery housing preferably comprises a stainless steel sheet. Further, it may comprise an aluminum alloy, a titanium clad stainless steel sheet, a copper clad stainless steel sheet or a nickel plating steel sheet.
- the positive electrode can 505 illustrated in FIG. 5 and the negative electrode can 608 illustrated in FIG. 6 also function as the battery housing (case) and as a terminal, and therefore stainless steel is preferable.
- the material constituting the battery housing can include, in addition to stainless steel, a metallic material of iron or zinc, a plastic material of polypropylene or the like, a complexed material comprising a metallic material or a glass fiber and a plastic material.
- a safety valve 614 may be provided in order to ensure safety when the internal pressure in the battery is increased.
- the safety valve may comprise, for example, rubber, a spring, a metal ball or a rupture disk. Examples
- Grained silicon (purity 99.6%) was mixed with a lump of titanium in an atomic ratio of 85:15 (weight ratio of 76.8:23.2), then formed in a vacuum into an Si-Ti alloy using an arc welder.
- the Si-Ti alloy was melted using a single roll method apparatus to form a molten metal, which was rapidly cooled by blowing at a revolving copper roll in argon gas to prepare an Si-Ti alloy.
- the Si-Ti alloy was then pulverized for 2 hours with a planetary-type ball mill using silicon nitride balls in an argon gas atmosphere to obtain a fine powder for an electrode material. (Example 2)
- Grained silicon (purity 99.6%) was mixed with a lump of titanium and a lump of boron in an atomic ratio of 85:15:0.85 (weight ratio of 76.8:23.2:0.3), then formed in a vacuum into a boron doped Si-Ti alloy using an arc welder.
- the boron doped Si- Ti alloy was melted using a single roll method apparatus to give a molten metal, which was rapidly cooled by blowing at a revolving copper roll in argon gas to prepare a boron doped Si-Ti alloy.
- the boron doped Si-Ti alloy was then pulverized for 2 hours with a planetary-type ball mill using silicon nitride balls in an argon gas atmosphere to obtain a fine powder for an electrode material. (Example 3)
- Grained silicon (purity 99.6%) was mixed with a lump of titanium in an atomic ratio of 85:15 (weight ratio of 76.8:23.2), then formed in a vacuum into an Si-Ti alloy using an arc welder.
- the Si-Sn-Ti alloy was then pulverized for 2 hours with a planetary-type ball mill using silicon nitride balls in an argon gas atmosphere to obtain a fine powder for an electrode material. (Example 4)
- Silicon, tin and aluminum were mixed in. an atomic ratio of 74.0:19.4:6.6 (weight ratio of 60:35:5), and melted using a single roll method apparatus to give a molten metal.
- This molten metal was rapidly cooled by blowing at a revolving copper roll in argon gas to obtain an Si-Sn-Al alloy.
- the Si-Sn-Al alloy was then pulverized for 2 hours with a planetary-type ball mill using silicon nitride balls in an argon gas atmosphere to obtain a fine powder for an electrode material.
- Example 6 Silicon, zinc and aluminum were mixed in an atomic ratio of 69.0:27.6:0.4 (weight ratio of 50.5:47.1:2.4), and melted in an argon gas atmosphere to give a molten metal, to obtain an Si-Zn-Al alloy powder using a gas atomization method injecting the melted metal in an atmosphere of an argon gas.
- the Si-Zn-Al alloy powder was pulverized in isopropyl alcohol with a media mill using zirconia beads to give an Si-Zn-Al alloy fine powder having an average particle diameter of 0.3 ⁇ m for an electrode material,
- This Si-Zn-Al alloy fine powder was further pulverized for 2 hours with a planetary-type ball mill using silicon nitride balls in an argon gas atmosphere to obtain a fine powder for an electrode material .
- Example 7 Example 7
- Silicon, aluminum and copper were mixed in an atomic ratio of 73.5:21.9:4.6 (weight ratio of 70:20:10), and melted using a single roll method apparatus to give a molten metal.
- This molten metal was rapidly cooled by blowing at a revolving copper roll in argon gas to obtain an Si-Al-Cu alloy.
- the Si-Al-Cu alloy was then pulverized for 2 hours with a planetary-type ball mill using silicon nitride balls in an argon gas atmosphere to obtain an Si-Al-Cu alloy fine powder for an electrode material.
- Example 8 An Si-Sn-Al-Ti alloy powder for an electrode material was obtained according to the same method as Example 6, except for the mixing of silicon, tin, aluminum and titanium in an atomic ratio of 84.1:11.5:0.4:4.0 (weight ratio of 59.8:35.0:0.2:5.0), to obtain an Si-Sn-Al-Ti alloy powder using the gas atomization method of Example 6. (Example 9)
- Silicon, tin and zinc were mixed in an atomic ratio of 81.0:16.2:2.8 (weight ratio of 51.9:43.9:4.2), and melted using a single roll method apparatus to give a molten metal.
- This molten metal was then injected with a highly pressurized water using a water atomization method to give an Si-Sn-Zn alloy.
- the Si-Sn-Zn alloy powder was pulverized in isopropyl alcohol with a media mill using zirconia beads to give an Si-Sn-Zn alloy fine powder having an average particle diameter of 0.3 ⁇ m for an electrode material.
- This Si-Sn-Zn alloy fine powder was further pulverized for 2 hours with a planetary-type ball mill using silicon nitride balls in an argon gas atmosphere to obtain a fine powder for an electrode material.
- An Si-Sn-Ag alloy powder for an electrode material was obtained according to the same method as Example 5, except for the mixing of silicon, tin and silver in an atomic ratio of 81.8:17.1:1.1 (weight ratio of 63:35:2), to obtain an Si-Sn-Ag alloy powder using the single roll method apparatus of Example 5. (Example 11)
- Si-Sn-Zn-Ti alloy powder for an electrode material was obtained according to the same method as Example 5, except for the mixing of silicon, tin, zinc, and titanium in an atomic ratio of 82.7:11.3:2.0:4.0 (weight ratio of 58.0:33.9:3.3:4.8), to obtain an Si-Sn-Zn-Ti alloy powder using the water atomization method of Example 9. (Example 12)
- Si-Sn-Sb alloy powder for an electrode material was obtained according to the same method as Example 12, except for the mixing of silicon, tin and antimony in a weight ratio of 58:34:8, to obtain an Si-Sn-Sb alloy powder using a single roll method apparatus .
- Example 14 An Si-Sn-Sb alloy powder for an electrode material was obtained according to the same method as Example 12, except for the mixing of silicon, tin and antimony in a weight ratio of 58:34:8, to obtain an Si-Sn-Sb alloy powder using a single roll method apparatus .
- An Si-Sn-Sb-B alloy powder for an electrode material was obtained according to the same method as Example 12, except for the mixing of silicon, tin, antimony and boron in a weight ratio of 60:35:4:1, to obtain an Si-Sn-Sb-B alloy powder using a single roll method apparatus .
- An Si-Sn-Cu-B alloy powder for an electrode material was obtained according to the same method as Example 12, except for the mixing of silicon, tin, copper and boron in a weight ratio of 59:34:5:2, to obtain an Si-Sn-Cu-B alloy powder using a single roll method apparatus .
- Example 16 An Si-Sn-Al-B alloy powder for an electrode material was obtained according to the same method as Example 12, except for the mixing of silicon, tin, aluminum and boron in a weight ratio of 59:34:5:2, to obtain an Si-Sn-Al-B alloy powder using a single roll method apparatus. (Example 17)
- Si-Sn-Al-Sb alloy powder for an electrode material was obtained according to the same method as Example 12, except for the mixing of silicon, tin, aluminum and antimony in a weight ratio of 56:33:4:7, to obtain an Si-Sn-Al-Sb alloy powder using a single roll method apparatus.
- Example 18 An Si-Sn-Al-Sb alloy powder for an electrode material was obtained according to the same method as Example 12, except for the mixing of silicon, tin, aluminum and antimony in a weight ratio of 56:33:4:7, to obtain an Si-Sn-Al-Sb alloy powder using a single roll method apparatus.
- An Si-Sn-Al-Sb-B alloy powder for an electrode material was obtained according to the same method as Example 12, except for the mixing of silicon, tin, aluminum, antimony and boron in a weight ratio of 58:34:5:2:1, to obtain an Si-Sn-Al-Sb-B alloy powder using a single roll method apparatus.
- Silicon powder having an average particle diameter of 10 ⁇ m and 99.6 wt% pure was pulverized in isopropyl alcohol with a media mill using zirconia beads to give an silicon fine powder having an average particle diameter of 0.3 ⁇ m.
- the silicon fine powder was then pulverized for 2 hours with a . planetary-type ball mill using silicon nitride balls in an argon gas atmosphere to obtain a fine powder for an electrode material.
- Grained silicon (purity 99.6%) was mixed with a lump of titanium in an atomic ratio of 65:35 (weight ratio of 52:48), then formed in a vacuum into an Si- Ti alloy using an arc welder.
- the Si-Ti alloy was melted using a single roll method apparatus to give a molten metal, which was rapidly cooled by blowing at a revolving copper roll in argon gas to prepare an Si-Ti alloy.
- the Si-Ti alloy was then pulverized for 2 hours with a planetary-type ball mill using silicon nitride balls in an argon gas atmosphere to obtain a fine powder for an electrode material.
- Grained silicon (purity 99.6%) was mixed with grained nickel in an atomic ratio of 65.9:34.1 (weight ratio of 48:52), then formed in a vacuum into an Si-Ni alloy using an arc welder.
- the Si-Ni alloy was melted using a single roll method apparatus to give a molten metal, which was rapidly cooled by blowing at a revolving copper roll in argon gas to prepare an Si-Ni alloy.
- the Si-Ni alloy was then pulverized for 2 hours with a planetary-type ball mill using silicon nitride balls in an argon gas atmosphere to obtain a fine powder for an electrode material.
- Silicon and nickel are known for their forming of intermetallic compounds (such as NiSi 2 , NiSi, Ni 2 Si 3 and Ni 2 Si) .
- the above composition of silicon and nickel tends to form NiSi 2 .
- the silicon alloy crystal structure of the present invention suitable for the negative electrode of a lithium secondary battery comprises, for example, the following features: that silicon intermetallic compounds are small in number, as they are thought to lower lithium storage performance; that the crystals for each of the elements forming the alloy are microcrystals or have been amorphous; and that the distribution of elements in the alloy is uniform, without segregation.
- the methods used for the analysis were X-ray diffraction analysis, observation by transmission electron microscope, energy dispersive X-ray spectroscopy (often called EDXS) analysis, electron diffraction analysis and the like.
- intermetallic compounds can be confirmed from an X-ray diffraction chart or electron diffraction chart.
- the crystals are microcrystals or have been amorphized, the half value width of the X-ray diffraction peak becomes broad, whereby the crystallite size calculated from Scherrer' s formula is small.
- the electron diffraction chart goes from a ring pattern to a halo pattern, and high-resolution observation using a transmission electron microscope shows tiny stripes or a maze-like pattern in the crystal lattice structure.
- Examples 1 to 18 were checked for silicon intermetallic compounds using selected-area electron diffraction from the X- ray diffraction and transmission electron microscope. Examples 1 to 4, 7, 8, 11 and 15, which were alloys containing titanium or copper, showed trace amounts of intermetallic compounds .
- Comparative Example 2 contained TiSi 2 intermetallic compounds and that Comparative Example 3 contained NiSi 2 intermetallic compounds .
- Comparative Examples 2 and 3 both had a large amount of segregation shading among the alloy particles. Further, from elemental mapping which combined EDXS analysis with the transmission electron microscope, it was confirmed .that nickel or titanium were segregated among the alloy particles.
- electrode structures were prepared ' using the fine powder of the respective silicon or silicon alloys obtained according to the above-described procedures, for evaluation of the lithium insertion/release performance of the electrodes.
- This slurry was applied to a electrodeposition copper foil (an electrochemically produced copper foil) having a thickness of 15 ⁇ m by means of a coater and dried, and the thickness was adjusted with a rollpress to obtain an electrode structure having an active material layer with a thickness of 25 ⁇ m.
- the resultant electrode structure was cut to a square size of 2.5 cm x 2.5 cm and a copper tub was welded to obtain a silicon electrode.
- [Evaluation Procedure for Lithium Charge/ Discharge (Insertion/Release) Amount] A lithium metal foil having a thickness of 100 ⁇ m was pressure bonded to a copper foil to obtain a lithium electrode.
- This aluminum-laminated film was a three-layered film comprising an outermost layer comprising a nylon film, a middle layer comprising an aluminum foil having a thickness of 20 ⁇ m and an inside layer comprising a laminated polyethylene film.
- the output terminal portions of each electrode were sealed by way of fusion.
- a lithium insertion/release cycle test charge/discharge cycle test
- the lithium electrode as the anode and the silicon electrode as the cathode were set in the above evaluation cell and the cell was connected to the charge/discharge apparatus.
- the evaluation cell was discharged at a current density of 0.112 mA/cm 2 (70 mA per 1 g of the active material layer of a silicon electrode, that is, 70 mA/the weight in grams of the electrode layer) to insert lithium in the electrode material layer of the silicon electrode
- the evaluation, cell was charged at a current density of 0.32 mA/cm 2 (200 mA/the weight in grams of the electrode layer) to release lithium from the electrode material layer of the silicon electrode, whereby the specific capacity per unit weight of the silicon electrode material layer, or the silicon powder or the silicon-based alloy powder, when lithium is inserted and released, was evaluated in a voltage range of 0 to 1.2 V.
- the results of the lithium insertion/release performance evaluation of the above electrode structure are as follows. First, for the first and tenth times, the ratio (efficiency) of electric charge resulting from lithium discharge compared with the electric charge resulting from lithium insertion was evaluated. For Comparative Examples 2 and 3 the first time efficiency was about 8 ' 5%, and tenth time efficiency 98% or less. In contrast, for the electrodes prepared from the electrode material of Examples 1 to 18 of the present invention, first time efficiency was about 92% or above, and the tenth time efficiency was 99.5% or above.
- the lithium discharged (released) electric charge on the tenth time had decreased to as low as 87% or less of that from the first time, In contrast, for electrodes prepared with the present electrode material, the lithium discharge electric charge on the tenth time was maintained at about 100% that of the first time.
- the lithium insertion/release efficiency of the first and tenth times were respectively 89% and 98%.
- the lithium discharge electric charge at the tenth time had dropped to 70% of that at the first time.
- the electric charge resulting from lithium discharge on the first time was as follows.
- all showed an electric charge of 1400 to 1800 mAh/g per electrode layer weight (excluding the current collector weight) .
- the electrode prepared from the silicon fine powder of Comparative Example 1 showed a lithium first discharge electric charge of 2000 mAh/g per electrode layer weight.
- the electrodes prepared from the alloy fine powder of Comparative Examples 2 and 3 showed a lithium discharge electric charge of 400 or less mAh/g per electrode layer weight.
- the silicon alloy electrodes prepared in the present examples have a longer cycle life, and can store and discharge about 4 to 6 times more electric charge (per electrode layer weight) than electrodes prepared from graphite.
- Table 1 also shows the release (discharge) efficiency of the first insertion when an electrochemical Li insertion/release reaction occurred, and the electric charge resulting from Li discharge for the electrodes prepared using an alloy fine powder which had been treated with a ball mill.
- Table 1 shows that the release (discharge) efficiency for a first time lithium insertion is very high, and that the electric charge resulting from Li discharge per electrode layer weight is also very high. Further, while amorphization can be performed by treating with a ball mill, the results confirm that the alloy which had boron added in high concentration generally has a broad half width of peak relating to silicon from the X-ray diffraction chart even prior to ball mill treatment, and easily amorphizes . From experience, it is known that a lithium secondary battery using an amorphized negative electrode has a long charge/discharge cycle life.
- each of the electrode material from Examples 1 to 18 was used to prepare a slurry in the same way as the preparation of the above electrode structure. Slurry was applied onto a polyester sheet, allowed to dry, then pressed with a roll press to give a sample electrode layer. The sheet resistance for this electrode layer was measured using a four-probe measurement method. The results showed that in all cases the electrode layers prepared from an electrode material doped with boron had a lower sheet resistance value than those that were not doped with boron.
- Example 19 a secondary battery was prepared as Example 19 of the present invention.
- an electrode structure provided with electrode layers on both sides of the current collector was prepared using the negative electrode material according to the present invention,
- the electrode structure thus prepared was used as a negative electrode, wherein a lithium secondary battery having 18650 size (diameter 18 mm ⁇ x height 65 mm) and a cross-sectional structure as shown in FIG. 6 was prepared.
- the negative electrode 603 was prepared according to the following procedure using each of the silicon alloy fine powders from Examples 1 to 18 as an electrode material.
- a flat graphite powder as a conductive auxiliary material (specifically, graphite powder having a disk-like shaped particles having a diameter of about 5 ⁇ m and a thickness of about 1 ⁇ m)
- a graphite powder nearly-round shaped particles having an average particle size in a range of from 0.5 to 1.0 ⁇ m
- 4.0% by weight of an acetylene black powder nearly-round shaped particles having an average particle size of 4 x 10 ⁇ 2 ⁇ m
- 11% by weight of the solid content of an adhesion agent (binder) which was calculated as a solid content from an N-methyl-2-pyrrolidone solution of
- Lithium citrate and cobalt nitrate were mixed at a mol ratio of 1:3, to which mixture citric acid was added and dissolved in ion-exchanged water to obtain a solution.
- the solution was sprayed in an air stream of 200°C to prepare an Li-Co oxide precursor fine powder.
- the Li-Co oxide precursor fine powder prepared in the above was subjected to heat treatment in an air stream of 850°C.
- Separator 607 A microporous polyethylene film having a thickness of 25 ⁇ m and was used as the separator.
- Assembly was entirely conducted in a dry atmosphere controlled with respect to water with a dew point of -50°C or less.
- the separator 607 was sandwiched between the negative electrode 603 and the positive electrode 606, then spirally wound so as to form a structure of separator/positive electrode/separator/negative electrode/separator, and inserted in negative electrode can 608 made of stainless steel, (ii) Next, the negative electrode lead 612 was spot- welded to a bottom portion of the negative electrode can 608. A necking was formed at an upper portion of the negative electrode can by means of a necking apparatus, and the positive electrode lead 613 was welded to the. positive electrode cap 609 provided with a gasket 610 made of polypropylene by means of spot welding machine .
- an electrode structure provided with electrode layers on both sides of the current collector was prepared using the negative electrode material according to the present invention,
- the electrode structure thus prepared was used as a negative electrode, wherein a lithium secondary battery having 18650 size (diameter 18 mm ⁇ x height 65 mm) and a cross-sectional structure as shown in
- FIG. 6 was prepared.
- Silicon, tin and boron were mixed in the ratio of 74.5:25.0:0.5 by weight and melted in an argon gas atmosphere to give a molten metal.
- the molten metal was injected by argon gas into a high-revolution water stream, to give an Si-Sn-B alloy powder.
- the Si-Sn-B alloy powder was pulverized in isopropyl alcohol with a media mill using zirconia beads to give an Si-Sn-B alloy fine powder having an average particle diameter of 0.3 ⁇ m.
- This Si-Sn-B alloy fine powder was further pulverized for 2 hours with an agitator using stainless steel balls in an argon gas atmosphere.
- this Si-Sn-B alloy fine powder To 100 parts by weight of this Si-Sn-B alloy fine powder, 2 parts of graphite powder, 1 part carbon fiber and 1 part multilayer carbon nanotube were added then pulverized to obtain a silicon fine powder complexed with a carbonaceous material for an electrode material. Next, 69% by weight of the obtained silicon alloy • fine powder complexed with the carbonaceous material was mixed with 10.0% by weight of a flat graphite powder as a conductive auxiliary material (specifically, graphite powder having a disk-like shaped particles having a diameter of about 5 ⁇ m and a thickness of about 1 ⁇ ) ,.
- a flat graphite powder as a conductive auxiliary material
- This electrode structure was cut to a specified size, then a nickel ribbon lead was attached by spot welding to the top of the electrode, and dried at 200°C under reduced pressure to prepare the negative electrode 603.
- the battery was prepared in the same way as in Example 19.
- Silicon, tin and boron were mixed in the ratio of 74.5:25.0:0.5 by weight and melted in an argon gas atmosphere to give a molten metal.
- the molten metal was injected with highly pressurized water to obtain an Si-Sn-B alloy powder.
- the Si-Sn-B alloy powder was pulverized in isopropyl alcohol with a media mill using zirconia beads to give an Si-Sn-B alloy fine powder having an average particle diameter of 0.3 ⁇ m for an electrode material.
- This Si-Sn-B alloy fine powder was further pulverized for 2 hours with an agitator using stainless steel balls in an argon gas atmosphere.
- silicon alloy fine powder was mixed with 10.0% by weight of a flat graphite powder as a conductive auxiliary material (specifically, graphite powder having a disk-like shaped particles having a diameter of about 5 ⁇ m and a thickness of about 1 ⁇ m) , 10.0% by weight of a graphite powder (nearly-round shaped particles having an average particle size in a range of from 0.5 to 1.0 ⁇ m) , and 11% by .weight of solid content calculated from an N-methyl-2-pyrrolidone solution of polyamic acid (polyimide precursor) of 14% concentration solid content, and N-methyl-2- pyrrolidone was added to the mixture to obtain a slurry.
- a flat graphite powder as a conductive auxiliary material
- a graphite powder nearly-round shaped particles having an average particle size in a range of from 0.5 to 1.0 ⁇ m
- the slurry was applied on both surfaces of a field copper foil (an electrochemically produced copper foil) having a thickness of 10 ⁇ m by means of a coater and dried, and' the thickness was adjusted with a roll press to obtain an electrode structure having an active material layer with a thickness of
- Lithium citrate and cobalt nitrate were mixed at a mol ratio of 1:3, and 0.1 mol ratio of yttrium nitrate (Y(N0 3 ) 3 * 6H 2 0) for Li element of lithium citrate, 0.4 mol ratio of zirconium oxyacetate (ZrO (CH 3 C00) 2 ) for Li element and citric acid were added to the mixture to form a solution, which was dissolved in ion-exchanged water.' This solution was sprayed in an air stream of 200°C to adjust a fine powder lithium-cobalt oxide precursor.
- silicon alloy particles having a microstructure can be prepared, in which a microcrystal or amorphous material of an element other than silicon is dispersed in microcrystalline silicon or amorphized silicon, by selecting an element composition containing a eutectic, wherein silicon and an element other than silicon constituting the silicon alloy form a uniform solution in a melted state and in which crystallization of silicon intermetallic compounds is less generated. Further, by doping this silicon alloy fine powder having microstructure with an element such as boron, it is possible to form an electrode material having a low resistance, high charging/discharging efficiency, high capacity for a lithium secondary battery. An electrode structure formed by the electrode material can highly efficiently and repeatedly store and discharge a large amount of lithium. When this electrode structure is used as the negative electrode to form a lithium secondary battery, a secondary battery having a high capacity and a high energy density can be prepared.
Abstract
Description
Claims
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Also Published As
Publication number | Publication date |
---|---|
CN101179126A (en) | 2008-05-14 |
EP1604415B1 (en) | 2012-11-21 |
CN1765024A (en) | 2006-04-26 |
EP2302720A1 (en) | 2011-03-30 |
WO2004086539B1 (en) | 2004-12-29 |
EP2302720B1 (en) | 2012-06-27 |
US20060040182A1 (en) | 2006-02-23 |
EP1604415A1 (en) | 2005-12-14 |
JP2010135336A (en) | 2010-06-17 |
EP1604415A4 (en) | 2009-01-28 |
KR100721500B1 (en) | 2007-05-23 |
TW200425569A (en) | 2004-11-16 |
JP5517637B2 (en) | 2014-06-11 |
CN101179126B (en) | 2011-09-28 |
KR20050114698A (en) | 2005-12-06 |
CN100382362C (en) | 2008-04-16 |
US20090061322A1 (en) | 2009-03-05 |
TWI235517B (en) | 2005-07-01 |
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