CA2623629C - Positive electrode active material and method of producing the same and nonaqueous electrolyte battery having positive electrode containing positive electrode active material - Google Patents
Positive electrode active material and method of producing the same and nonaqueous electrolyte battery having positive electrode containing positive electrode active material Download PDFInfo
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- H01M4/36—Selection of substances as active materials, active masses, active liquids
- H01M4/58—Selection of substances as active materials, active masses, active liquids of inorganic compounds other than oxides or hydroxides, e.g. sulfides, selenides, tellurides, halogenides or LiCoFy; of polyanionic structures, e.g. phosphates, silicates or borates
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- H01M4/13—Electrodes for accumulators with non-aqueous electrolyte, e.g. for lithium-accumulators; Processes of manufacture thereof
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- 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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Abstract
Description
POSITIVE ELECTRODE ACTIVE MATERIAL AND METHOD OF PRODUCING THE
SAME AND NONAQUEOUS ELECTROLYTE BATTERY HAVING POSITIVE
ELECTRODE CONTAINING POSITIVE ELECTRODE ACTIVE MATERIAL
TECHNICAL FIELD
[0001] The present invention relates to an olivine-type positive electrode active material that is an inexpensive and very safe positive electrode active material that also exhibits excellent battery properties even at high energy densities. The present invention also relates to a method of producing this olivine-type positive electrode active material and to a nonaqueous electrolyte battery that has a positive electrode that contains this olivine-type positive electrode active material.
BACKGROUND ART
However, LiNi02 has a problem with the safety of its charged state, while LiMn204 has a problem with chemical stability in high temperature regions. Novel positive electrode materials that combine these elements have been proposed for small batteries, but there has been demand for novel replacement materials for the positive electrode active material for large batteries, where the cost and safety requirements are more stringent.
However, when the present inventors produced positive electrode active materials in which a portion of the Mn was replaced by a single selection from Co, Ni, Ti, and so forth as proposed in these patent references, and then fabricated batteries using these positive electrode active materials, the present inventors were unable to confirm an improvement in the capacity of these batteries. The present inventors were also unable to confirm a plateau at around 4 V in constant-current charge-discharge testing of these batteries.
A problem here, however, is that the specific surface area of the positive electrode active material is increased by the addition of high specific surface area carbon particles and by the coating of the positive electrode active material by such carbon particles. This increase in the specific surface area causes a reduction in the dispersibility of the positive electrode active material in paint and thereby makes it difficult to uniformly coat the positive electrode active material at high densities on an electrode.
Patent document 1: Japanese Patent Laid-open Publication No. 2001-307731 Patent document 2: Japanese Patent Laid-open Publication No. 2003-257429 Patent document 3: Japanese Patent Laid-open Publication No. 2004-63270 Patent document 4: Japanese Patent Laid-open Publication No. 2001-15111 Patent document 5: Japanese Patent Laid-open Publication No. 2002-110163 Patent document 6: Japanese Patent Laid-open Publication No. 2003-34534 Patent document 7: Japanese Patent Laid-open Publication No. 2003-229127 Non-Patent document 1: by D. Arcon, A. Zorko, P. Cevc, R.
Dominko, M. Bele, J. Jamnik, Z. Jaglicic, and I. Golosovsky, Journal of Physics and Chemistry of Solids, 65, 1773-1777 (2004) Non-Patent document 2: A. Yamada, M. Hosoya, S. Chung, Y.
Kudo, K. Hinokuma, K. Liu, and Y. Nishi, Journal of Power Sources, 119-121, 232-238 (2003) Non-Patent document 3: Guohua Li, Hideto Azuma, and Masayuki Tohda, Electrochemical and Solid-State Letters, 5(6), A135-A137 (2002) Non-Patent document 4: H. Huang, S. C. Yin, and L. F.
Nazar, Electrochemical and Solid-State Letters, 4(10), A170-A172 (2001) Non-Patent document 5: Z. Chen and J. R. Dahn, Journal of the Electrochemical Society, 149 (9), A1184-A1189 (2002) DISCLOSURE OF THE INVENTION
PROBLEM TO BE SOLVED BY THE INVENTION
MEANS FOR SOLVING THE PROBLEMS
0.2 and 0 < w < 0.2.
mixing a pre-calcination precursor for an olivine-type lithium manganese phosphate compound represented by the following general formula (1) LixMnyMaPO4 (1) (in the formula, 0 < x < 2, 0 < y < 1, 0 < a < 1, and M is at least one metal element selected from the group consisting of Co, Ni, Fe, Zn, Cu, Ti, Sn, Zr, V. and Al) with a carbon source; and calcining the obtained mixture.
to [13], wherein the carbon source comprises carbon particles or a carbon precursor, or carbon particles and a carbon precursor.
to [15], wherein calcination is carried out under an inert gas atmosphere or a reducing atmosphere.
to [13], wherein the carbon source is at least one selected from the group consisting of glucose, cellulose acetate, pyromellitic acid, acetone, and ethanol.
BRIEF DESCRIPTION OF THE DRAWINGS
Fig. 2 is a scanning electron photomicrograph of the positive electrode active material produced in Example 1;
Fig. 3 is a graph that shows the results of a constant-current charge-discharge test on the basic lithium secondary battery fabricated in Example 1;
Fig. 4 is a scanning electron photomicrograph of the positive electrode active material produced in Example 2;
Fig. 5 is a graph that shows the results of a constant-current charge-discharge test on the basic lithium secondary battery fabricated in Example 2;
Fig. 6 is a scanning electron photomicrograph of the positive electrode active material produced in Example 3;
Fig. 7 is a graph that shows the results of a constant-current charge-discharge test on the basic lithium secondary battery fabricated in Example 3;
Fig. 8 is a scanning electron photomicrograph of the positive electrode active material produced in Example 4;
Fig. 9 is a graph that shows the results of a constant-current charge-discharge test on the basic lithium secondary battery fabricated in Example 4;
Fig. 10 is a scanning electron photomicrograph of the positive electrode active material produced in Example 5;
Fig. 11 is a graph that shows the results of a constant-current charge-discharge test on the basic lithium secondary battery fabricated in Example 5;
Fig. 12 is a scanning electron photomicrograph of the positive electrode active material produced in Example 6;
Fig. 13 is a graph that shows the results of a constant-current charge-discharge test on the basic lithium secondary battery fabricated in Example 6;
Fig. 14 is a scanning electron photomicrograph of the positive electrode active material produced in Example 7;
Fig. 15 is a graph that shows the results of a constant-current charge-discharge test on the basic lithium secondary battery fabricated in Example 7;
Fig. 16 is a scanning electron photomicrograph of the positive electrode active material produced in Example 8;
Fig. 17 is a graph that shows the results of a constant-current charge-discharge test on the basic lithium secondary battery fabricated in Example 8;
Fig. 18 is a scanning electron photomicrograph of the positive electrode active material produced in Example 9;
Fig. 19 is a graph that shows the results of a constant-current charge-discharge test on the basic lithium secondary battery fabricated in Example 9;
Fig. 20 is a scanning electron photomicrograph of the positive electrode active material produced in Example 10;
Fig. 21 is a graph that shows the results of a constant-current charge-discharge test on the basic lithium secondary battery fabricated in Example 10;
Fig. 22 is a scanning electron photomicrograph of the positive electrode active material produced in Comparative Example 1;
Fig. 23 is a graph that shows the results of a constant-current charge-discharge test on the basic lithium secondary battery fabricated in Comparative Example 1;
Fig. 24 is a scanning electron photomicrograph of the positive electrode active material produced in Comparative Example 3;
Fig. 25 is a graph that shows the results of a constant-current charge-discharge test on the basic lithium secondary battery fabricated in Comparative Example 3;
Fig. 26 is a scanning electron photomicrograph of the positive electrode active material produced in Comparative Example 4;
Fig. 27 is a graph that shows the results of a constant-current charge-discharge test on the basic lithium secondary battery fabricated in Comparative Example 4;
Fig. 28 is a scanning electron photomicrograph of the positive electrode active material produced in Comparative Example 5;
Fig. 29 is a graph that shows the results of a constant-current charge-discharge test on the basic lithium secondary battery fabricated in Comparative Example 5;
Fig. 30 is a scanning electron photomicrograph of the positive electrode active material produced in Comparative Example 6;
Fig. 31 is a graph that shows the results of a constant-current charge-discharge test on the basic lithium secondary battery fabricated in Comparative Example 6;
Fig. 32 is a graph that shows the results of a constant-current charge-discharge cycle test on the basic lithium secondary battery fabricated in Example 3;
Fig. 33 is a graph that shows the results of a constant-current charge-discharge cycle test on the basic lithium secondary battery fabricated in Comparative Example 3;
Fig. 34 is a schematic diagram of a nonaqueous electrolyte battery;
Fig. 35 is a schematic diagram of a nonaqueous electrolyte battery fabricated for use in constant-current charge-discharge testing;
Fig. 36 is a scanning electron photomicrograph of the positive electrode active material produced in Example 11;
Fig. 37 is a graph that shows the results of a constant-current charge-discharge test on the basic lithium secondary battery fabricated in Example 11;
Fig. 38 is a scanning electron photomicrograph of the positive electrode active material produced in Example 12;
Fig. 39 is a graph that shows the results of a constant-current charge-discharge test on the basic lithium secondary battery fabricated in Example 12;
Fig. 40 is a scanning electron photomicrograph of the positive electrode active material produced in Example 13;
Fig. 41 is a graph that shows the results of a constant-current charge-discharge test on the basic lithium secondary battery fabricated in Example 13;
Fig. 42 is a scanning electron photomicrograph of the positive electrode active material produced in Example 14;
Fig. 43 is a graph that shows the results of a constant-current charge-discharge test on the basic lithium secondary battery fabricated in Example 14;
Fig. 44 is a scanning electron photomicrograph of the positive electrode active material produced in Example 15; and Fig. 45 is a graph that shows the results of a constant-current charge-discharge test on the basic lithium secondary battery fabricated in Example 15.
BEST MODE FOR CARRYING OUT THE INVENTION
The positive electrode active material of the present invention comprises an olivine-type lithium manganese phosphate compound represented by the following general formula (1) Li,MnyMaPO4 (1) (in the formula, 0 < x < 2, 0 < y < 1, 0 < a < 1, and M is at least one metal element selected from the group consisting of Co, Ni, Fe, Zn, Cu, Ti, Sn, Zr, V. and Al) and has a particle diameter of 10 to 500 nm.
The x, y, and a that indicate the proportions of the elements in this compound can respectively vary within the numerical ranges given by 0 < x < 2, 0 < y < 1, and 0 < a < 1 so as to strike a charge balance for the compound. While the molar ratio a for the substituting metal can assume a value of 0.2 or more, it is preferably 0 < a < 0.4 and more preferably is 0 < a < 0.2 when one considers the contribution to improving the battery capacity and the cost of the substituting metal. On the other hand, the molar ratio y for the Mn can be freely established in the range of 0 < y < 1, but is ordinarily 0.8 <
y < 1Ø
Substitution can again be 0.2 or more, but 0 < z < 0.2 and 0 <
w < 0.2 are preferred when one considers the contribution to improving the battery capacity and the cost of the substituting metal. In particular, the crystal structure is readily stabilized when Mn replacement is carried out using z = w. On the other hand, the molar ratio y for the Mn can be freely established in the range of 0 < y < 1, but is ordinarily 0.8 < y < 1Ø
The positive electrode active material of the present invention can be produced by the methods for known olivine-type lithium manganese phosphate (LimnPO4), with the difference that in the present case the salt of the substituting metal is included in the pre-calcination precursor.
A very suitable pre-calcination precursor is, for example, the coprecipitated product obtained by a process comprising mixing an aqueous manganese salt solution with an aqueous H3PO4 solution, an aqueous LiOH solution, and an aqueous solution containing the salt of at least one metal selected from the group consisting of Co, Ni, Fe, Zn, Cu, Ti, Sn, Zr, V, and Al and then holding the obtained mixed solution at 50 to 100 C to produce a coprecipitated product.
(1) While stirring, the aqueous solutions of the M1 salt and M2 salt, the aqueous H3PO4 solution, and the aqueous LiOH
solution are added in the given sequence to the aqueous Mn salt solution in the temperature range of 10 to 100 C; this is followed by mixing at 50 to 100 C to obtain the coprecipitated product; the coprecipitated product is filtered off, washed with water, and dried to obtain a pre-calcination precursor;
and the obtained pre-calcination precursor is calcined in an inert gas atmosphere or in a reducing atmosphere.
(2) While stirring, the aqueous solutions of the M1 salt and M2 salt, the aqueous H3PO4 solution, and the aqueous LiOH
solution are added in the given sequence to the aqueous Mn salt solution in the temperature range of 10 to 100 C; this is followed by stirring while holding at 50 to 100 C to obtain the coprecipitated product; the coprecipitated product is filtered off, washed with water, and dried to obtain a pre-calcination precursor; and the obtained pre-calcination precursor is mixed with a carbon source and calcined in an inert gas atmosphere or in a reducing atmosphere.
The reducing atmosphere can be exemplified by hydrogen and by lower hydrocarbons, for example, C1_4 alkanes such as methane, ethane, propane, and butane.
(Battery structure) An example of a nonaqueous electrolyte battery that uses the positive electrode active material of the present invention will be described with reference to the drawings appended herewith. A cross-sectional drawing that shows a schematic of the battery is given in Fig. 34. Broadly speaking, the nonaqueous electrolyte battery 1 in this figure has a negative electrode member 2, which functions as an external negative electrode for the battery; a positive electrode member 3, which functions as an external positive electrode for the battery; and, situated between the preceding two members in the sequence given, a negative electrode current collector 4, a negative electrode active material 5, a separator 8, a positive electrode active material 7, and a positive electrode current collector 6. The negative electrode member 2 has an approximately cylindrical shape and is configured so as to be able to hold the negative electrode current collector 4 and the negative electrode active material in its interior. The positive electrode member 3, on the other hand, also has an approximately cylindrical shape and is configured so as to be able to hold the positive electrode current collector 6 and the positive electrode active material 7 in its interior. The radial dimension of the positive electrode member 3 and the radial dimension of the separator 8 are set somewhat larger than the radial dimension of the negative electrode member 2, and the peripheral edge of the negative electrode member 2 is therefore overlapped by the peripheral edge of the separator 8 and the peripheral edge of the positive electrode member 3. The space in the interior of the battery is filled with a nonaqueous electrolyte 9, and a sealant 10 is placed in the overlap zone of the peripheral edges of the negative electrode member 2, the separator 8, and the positive electrode member 3, thereby maintaining the interior of the battery in an airtight condition.
and a layer of negative electrode active material 5 is formed on the negative electrode current collector. For example, nickel foil, copper foil, and so forth, can be used as the negative electrode current collector. A negative electrode active material capable of lithium insertion/de-insertion is used as the negative electrode active material, and, for example, lithium metal, lithium alloys, lithium-doped electroconductive polymers, layer compounds (carbon materials, metal oxides, and so forth), and the like, are specifically used. The binder present in the negative electrode active material layer can be a resin material as generally known for use as a binder in the negative electrode active material layer of nonaqueous electrolyte batteries of this type. In particular, because lithium metal foil can be used not only for the negative electrode active material, but also for the negative electrode current collector, a simple and convenient battery structure can be elaborated by using lithium metal foil for the negative electrode.
and a layer of positive electrode active material 7 is formed on the positive electrode current collector. The positive electrode active material of the present invention as described hereinabove is used as the positive electrode active material. The positive electrode current collector can be, for example, aluminum foil and so forth. The binder present in the positive electrode active material layer can be a resin material, for example, polyvinylidene fluoride and so forth, as generally known for use as a binder in the positive electrode active material layer of nonaqueous electrolyte batteries of this type. The positive electrode active material layer can contain an electroconductive material in order to raise the electroconductivity. This electroconductive material can be exemplified by graphite, acetylene black, and so forth.
A lithium salt, for example, LiPF6, L1C104, L1AsF6, LiBF4, LiCF3S03, LiN(CF3S02)2, and so forth, can be used as the electrolyte. The use of LiPF6 and LiBF4 is preferred among the preceding lithium salts. The solid electrolyte can be exemplified by solid inorganic electrolytes such as lithium nitride, lithium iodide, and so forth, and by organic polymer electrolytes such as poly(ethylene oxide), poly(methacrylate), poly(acrylate), and so forth. In addition, there are no particular restrictions on the material that can be used to form an electrolyte gel as long as this material can absorb a liquid electrolyte as described above with gelation; examples here are fluoropolymers such as poly(vinylidene fluoride), vinylidene fluoride/hexafluoropropylene copolymer, and so forth.
The obtained slurry is uniformly coated on the current collector and dried thereon to form a layer of negative electrode active material. The resulting laminate comprising the negative electrode current collector and the negative electrode active material layer is then installed within the negative electrode member in such a manner that the negative electrode current collector and the interior surface of the negative electrode member are in contact, thereby forming the negative electrode. In addition, lithium metal foil can also be directly used as the negative electrode current collector and the negative electrode active material as described above.
The resulting laminate comprising the positive electrode current collector and the positive electrode active material layer is then installed in the positive electrode member in such a manner that the positive electrode current collector is in contact with the inner surface of the positive electrode member, thereby forming the positive electrode.
and the nonaqueous electrolyte battery is completed by sealing the battery interior with sealant.
EXAMPLES
during the initial discharge. The cycle characteristics of the battery were evaluated through the change, as a function of the number of charge-discharge cycles, in the charge capacity (mAh/g) at 4500 mV during charging and the discharge capacity (mAh/g) at 3000 mV during discharge.
0.270 L of a 1.0 mol/L aqueous solution of Mn(CH3C00)2 was charged to a one-liter reactor, and to this were added 0.015 L
of a 1.0 mol/L aqueous solution of CoSO4 and 0.015 L of a 1.0 mol/L aqueous solution of Ti(SO4)2 with thorough stirring.
0.148 L of a 2.04 mol/L aqueous solution of H3PO4 was then added dropwise at 40 C and over 30 minutes and mixing was carried out for an additional 30 minutes. 0.450 L of a 2.0 mol/L aqueous LiOH solution was then added dropwise over 30 minutes, followed by heating to 100 C and stirring for 1 hour.
The resulting coprecipitated product was filtered off, washed with 1 L deionized water, and dried for 12 hours in a 140 C
oven; the resulting sample was ground in a mortar. 10 g of the resulting sample was pre-calcined for 24 hours at 350 C
under an N2 blanket and was thereafter subjected to main calcination for 24 hours at 700 C under an N2 blanket to give the positive electrode active material.
A lithium secondary battery was fabricated using the positive electrode active material obtained as described above.
Using N-methyl-2-pyrrolidone as the solvent, positive electrode active material : electroconductive material (acetylene black: Denka Black powder from Denki Kagaku Kogyo Kabushiki Kaisha, average particle size = 35 nm, specific surface area = 68 m2/g) : binder (polyvinylidene fluoride) were mixed at a weight ratio of 72 : 18 : 10 and kneaded into a paste-like slurry. This slurry was coated on an aluminum foil current collector and dried; punching into a circle with a diameter of 15 mm then gave a positive electrode. The mass of the positive electrode active material was 9 mg. A basic lithium secondary battery was then fabricated using a porous polyethylene carbonate membrane (diameter = 24 mm, thickness =
25 Ku) for the separator, a solution prepared by dissolving L1PF6 to a concentration of 1 M in a mixed solvent of ethylene carbonate and dimethyl carbonate (volumetric ratio = 1 : 1) as liquid electrolyte, and lithium metal punched into a circle (diameter = 16 mm, thickness = 0.2 mm) as the negative electrode. The basic lithium secondary battery fabricated in this example is shown schematically in Fig. 35.
The initial charge-discharge characteristics are shown in Table 2 and Fig. 3 (in the figures, "Chg. 1" indicates the initial charging curve, while "Dis. 1" indicates the initial discharge curve).
of a 1.0 mol/L aqueous solution of C0SO4 and 0.015 L of a 1.0 mol/L aqueous solution of Ti(SO4)2 with thorough stirring.
0.148 L of a 2.04 mol/L aqueous solution of H3PO4 was then added dropwise at 40 C and over 30 minutes and mixing was carried out for an additional 30 minutes. 0.450 L of a 2.0 mol/L aqueous LiOH solution was then added dropwise over 30 minutes, followed by heating to 100 C. 20.0 g polyvinyl alcohol (PVA, Kishida Chemical Co., Ltd., degree of polymerization = 1900 to 2100) was added and stirring was carried out for 1 hour. The resulting coprecipitated product was filtered off, washed with 1 L deionized water, dried for 12 hours in a 140 C oven, and ground in a mortar. 10 g of the resulting sample was pre-calcined for 24 hours at 350 C under an N2 blanket and was thereafter subjected to main calcination for 24 hours at 700 C under an N2 blanket. The resulting sample was analyzed as in Example 1. The results from the compositional analysis and x-ray diffraction measurement, the measured specific surface area, and the average particle diameter are shown in Table 1; the SEM photograph is shown in Fig. 4.
of a 1.0 mol/L aqueous solution of CoSO4 and 0.034 L of a 1.0 mol/L aqueous solution of Ti(SO4)2 with thorough stirring.
0.166 L of a 2.04 mol/L aqueous solution of H3PO4 was then added dropwise at 40 C and over 30 minutes and mixing was carried out for an additional 30 minutes. 0.406 L of a 2.5 mol/L aqueous LiOH solution was then added dropwise over 30 minutes, followed by heating to 100 C and stirring for 1 hour.
The resulting coprecipitated product was filtered off, washed with 1 L deionized water, and dried for 12 hours in a 140 C
oven. To 10 g of the resulting sample were added 2.05 g PVA
and 50 mL deionized water with thorough mixing. This sample was dried for 12 hours in a 140 C oven. The resulting mixture was ground with a mortar. It was then pre-calcined for 24 hours at 350 C under an N2 blanket and was thereafter subjected to main calcination for 24 hours at 700 C under an N2 blanket. The resulting sample was analyzed as in Example 1.
The results from the compositional analysis and x-ray diffraction measurement, the measured specific surface area, and the average particle diameter are shown in Table 1; the SEM photograph is shown in Fig. 6.
of a 1.0 mol/L aqueous solution of CoSO4 and 0.067 L of a 1.0 mol/L aqueous solution of Ti(SO4)2 with thorough stirring.
0.147 L of a 2.04 mol/L aqueous solution of H3PO4 was then added dropwise at 40 C and over 30 minutes and mixing was carried out for an additional 30 minutes. 0.450 L of a 2.0 mol/L aqueous LiOH solution was then added dropwise over 30 minutes, followed by heating to 100 C and stirring for 1 hour.
The resulting coprecipitated product was filtered off, washed with 1 L deionized water, and dried for 12 hours in a 140 C
oven. To 10 g of the resulting sample were added 2.05 g PVA
and 50 mL deionized water with thorough mixing. This sample was dried for 12 hours in a 140 C oven. The resulting mixture was ground with a mortar. It was then pre-calcined for 24 hours at 350 C under an N2 blanket and was thereafter subjected to main calcination for 24 hours at 700 C under an N2 blanket. The resulting sample was analyzed as in Example 1.
The results from the compositional analysis and x-ray diffraction measurement, the measured specific surface area, and the average particle diameter are shown in Table 1; the SEM photograph is shown in Fig. 8.
of a 1.0 mol/L aqueous solution of Ni(CH3C00)2 and 0.034 L of a 1.0 mol/L aqueous solution of Ti(SO4)2 with thorough stirring.
0.166 L of a 2.04 mol/L aqueous solution of H3PO4 was then added dropwise at 40 C and over 30 minutes and mixing was carried out for an additional 30 minutes. 0.405 L of a 2.5 mol/L aqueous LiOH solution was then added dropwise over 30 minutes, followed by heating to 100 C and stirring for 1 hour.
The resulting coprecipitated product was filtered off, washed with 1 L deionized water, and dried for 12 hours in a 140 C
oven. To 10 g of the resulting sample were added 8.20 g PVA
and 50 mL deionized water with thorough mixing. This sample was dried for 12 hours in a 140 C oven. The resulting mixture was ground with a mortar. It was then pre-calcined for 24 hours at 350 C under an N2 blanket and was thereafter subjected to main calcination for 24 hours at 700 C under an N2 blanket. The resulting sample was analyzed as in Example 1.
The results from the compositional analysis and x-ray diffraction measurement, the measured specific surface area, and the average particle diameter are shown in Table 1; the SEM photograph is shown in Fig. 10.
of a 1.0 mol/L aqueous solution of FeC13 and 0.034 L of a 1.0 mol/L aqueous solution of Ti(SO4)2 with thorough stirring.
0.166 L of a 2.04 mol/L aqueous solution of H3PO4 was then added dropwise at 40 C and over 30 minutes and mixing was carried out for an additional 30 minutes. 0.406 L of a 2.5 mol/L aqueous LiOH solution was then added dropwise over 30 minutes, followed by heating to 100 C and stirring for 1 hour.
The resulting coprecipitated product was filtered off, washed with 1 L deionized water, and dried for 12 hours in a 140 C
oven. To 10 g of the resulting sample were added 2.05 g PVA
and 50 mL deionized water with thorough mixing. This sample was dried for 12 hours in a 140 C oven. The resulting mixture was ground with a mortar. It was then pre-calcined for 24 hours at 350 C under an N2 blanket and was thereafter subjected to main calcination for 24 hours at 700 C under an N2 blanket. The resulting sample was analyzed as in Example 1.
The results from the compositional analysis and x-ray diffraction measurement, the measured specific surface area, and the average particle diameter are shown in Table 1; the SEM photograph is shown in Fig. 12.
The results from the compositional analysis and x-ray diffraction measurement, the measured specific surface area, and the average particle diameter are shown in Table 1; the SEM photograph is shown in Fig. 14.
the SEM photograph is shown in Fig. 16.
of a 1.0 mol/L aqueous solution of C0SO4 and 0.015 L of a 1.0 mol/L aqueous solution of NiSO4 with thorough stirring. 0.148 L of a 2.04 mol/L aqueous solution of H3PO4 was then added dropwise at 40 C and over 30 minutes and mixing was carried out for an additional 30 minutes. 0.450 L of a 2.0 mol/L
aqueous LiOH solution was then added dropwise over 30 minutes, followed by heating to 100 C and stirring for 1 hour. The resulting coprecipitated product was filtered off, washed with 1 L deionized water, and dried for 12 hours in a 140 C oven.
To 10 g of the resulting sample were added 2.05 g PVA and 50 mL deionized water with thorough mixing. This sample was dried for 12 hours in a 140 C oven. The resulting mixture was ground with a mortar. It was then pre-calcined for 24 hours at 350 C under an N2 blanket and was thereafter subjected to main calcination for 24 hours at 700 C under an N2 blanket.
The resulting sample was analyzed as in Example 1. The results from the compositional analysis and x-ray diffraction measurement, the measured specific surface area, and the average particle diameter are shown in Table 1; the SEM
photograph is shown in Fig. 18.
of a 1.0 mol/L aqueous solution of FeC13 and 0.015 L of a 1.0 mol/L aqueous solution of Co(CH3C00)2 with thorough stirring.
0.148 L of a 2.04 mol/L aqueous solution of H3PO4 was then added dropwise at 40 C and over 30 minutes and mixing was carried out for an additional 30 minutes. 0.450 L of a 2.0 mol/L aqueous LiOH solution was then added dropwise over 30 minutes, followed by heating to 100 C and stirring for 1 hour.
The resulting coprecipitated product was filtered off, washed with 1 L deionized water, and dried for 12 hours in a 140 C
oven. To 10 g of the resulting sample were added 8.20 g PVA
and 50 mL deionized water with thorough mixing. This sample was dried for 12 hours in a 140 C oven. The resulting mixture was ground with a mortar. It was then pre-calcined for 24 hours at 350 C under an N2 blanket and was thereafter subjected to main calcination for 24 hours at 700 C under an N2 blanket. The resulting sample was analyzed as in Example 1.
The results from the compositional analysis and x-ray diffraction measurement, the measured specific surface area, and the average particle diameter are shown in Table 1; the SEM photograph is shown in Fig. 20.
aqueous solution of H3PO4 was then added dropwise at 40 C and over 30 minutes and mixing was carried out for an additional 30 minutes. 0.405 L of a 2.0 mol/L aqueous LiOH solution was thereafter added dropwise over 30 minutes, followed by heating to 100 C and stirring for 1 hour. The resulting coprecipitated product was filtered off, washed with 1 L
deionized water, and dried for 12 hours in a 140 C oven. The resulting mixture was ground with a mortar. 10 g of this sample was then pre-calcined for 24 hours at 350 C under an N2 blanket and was thereafter subjected to main calcination for 24 hours at 700 C under an N2 blanket. The resulting sample was analyzed as in Example 1. The results from the compositional analysis and x-ray diffraction measurement, the measured specific surface area, and the average particle diameter are shown in Table 1; the SEM photograph is shown in Fig. 22.
According to the results from the x-ray diffraction measurement, an olivine-type single phase pattern was not obtained at the calcination temperature of 600 C and unreacted L13PO4 was observed.
aqueous solution of H3PO4 was then added dropwise at 40 C and over 30 minutes and mixing was carried out for an additional 30 minutes. 0.405 L of a 2.0 mol/L aqueous LiOH solution was thereafter added dropwise over 30 minutes, followed by heating to 100 C and stirring for 1 hour. The resulting coprecipitated product was filtered off, washed with 1 L
deionized water, and dried for 12 hours in a 140 C oven. To g of the resulting sample were added 2.05 g PVA and 50 mL
deionized water with thorough mixing. This sample was dried for 12 hours in a 140 C oven. The resulting mixture was ground with a mortar. It was then pre-calcined for 24 hours at 350 C under an N2 blanket and was thereafter subjected to main calcination for 24 hours at 700 C under an N2 blanket.
The resulting sample was analyzed as in Example 1. The results from the compositional analysis and x-ray diffraction measurement, the measured specific surface area, and the average particle diameter are shown in Table 1; the SEM
photograph is shown in Fig. 24.
of a 1.0 mol/L aqueous solution of Ti(SO4)2 with thorough stirring. 0.147 L of a 2.04 mol/L aqueous solution of H3PO4 was then added dropwise at 40 C and over 30 minutes and mixing was carried out for an additional 30 minutes. 0.360 L of a 2.5 mol/L aqueous LiOH solution was then added dropwise over 30 minutes, followed by heating to 100 C and stirring for 1 hour. The resulting coprecipitated product was filtered off, washed with 1 L deionized water, and dried for 12 hours in a 140 C oven. To 10 g of the resulting sample were added 2.05 g starch and 50 mL deionized water with thorough mixing. This sample was dried for 12 hours in a 140 C oven. The resulting mixture was ground with a mortar. It was then pre-calcined for 24 hours at 350 C under an N2 blanket and was thereafter subjected to main calcination for 24 hours at 700 C under an N2 blanket. The resulting sample was analyzed as in Example 1.
The results from the compositional analysis and x-ray diffraction measurement, the measured specific surface area, and the average particle diameter are shown in Table 1; the SEM photograph is shown in Fig. 26.
of a 1.0 mol/L aqueous solution of CoSO4 with thorough stirring. 0.147 L of a 2.04 mol/L aqueous solution of H3PO4 was then added dropwise at 40 C and over 30 minutes and mixing was carried out for an additional 30 minutes. 0.360 L of a 2.5 mol/L aqueous LiOH solution was then added dropwise over 30 minutes, followed by heating to 100 C and stirring for 1 hour. The resulting coprecipitated product was filtered off, washed with 1 L deionized water, and dried for 12 hours in a 140 C oven. To 10 g of the resulting sample were added 2.05 g starch and 50 mL deionized water with thorough mixing. This sample was dried for 12 hours in a 140 C oven. The resulting mixture was ground with a mortar. It was then pre-calcined for 24 hours at 350 C under an N2 blanket and was thereafter subjected to main calcination for 24 hours at 700 C under an N2 blanket. The resulting sample was analyzed as in Example 1.
The results from the compositional analysis and x-ray diffraction measurement, the measured specific surface area, and the average particle diameter are shown in Table 1; the SEM photograph is shown in Fig. 28.
of a 1.0 mol/L aqueous solution of FeCl3 with thorough stirring. 0.147 L of a 2.04 mol/L aqueous solution of H3PO4 was then added dropwise at 40 C and over 30 minutes and mixing was carried out for an additional 30 minutes. 0.360 L of a 2.5 mol/L aqueous LiOH solution was then added dropwise over 30 minutes, followed by heating to 100 C and stirring for 1 hour. The resulting coprecipitated product was filtered off, washed with 1 L deionized water, and dried for 12 hours in a 140 C oven. To 10 g of the resulting sample were added 2.05 g starch and 50 mL deionized water with thorough mixing. This sample was dried for 12 hours in a 140 C oven. The resulting mixture was ground with a mortar. It was then pre-calcined for 24 hours at 350 C under an N2 blanket and was thereafter subjected to main calcination for 24 hours at 700 C under an N2 blanket. The resulting sample was analyzed as in Example 1.
The results from the compositional analysis and x-ray diffraction measurement, the measured specific surface area, and the average particle diameter are shown in Table 1; the SEM photograph is shown in Fig. 30.
Table 1. Composition and properties of the products calcina-fluorescent x-ray carbon-specific substi- analysis (mol% versus Mn) tion carbon particle contain-surface tuting condi-content XRD diameter ing area metal Mn P Li % tions % nm material m2ig C/hr , exam- 1 Co 5M%, Co:0.06 single none 1.00 0.98 0.98 700/24 0.02 183 9.8 Ti 5M% Ti:0.04 phase pies -2 Co 5M%, Co:0.06 single n PVA 1.00 1.02 1.01 700/24 6.13 102 27.0 Ti 5M% Ti:0.04 phase 0 -I.) 3 Co 10M%, Co:0.12 single m I.) PVA 1.00 1.09 1.07 700/24 4.13 113 28.8 --w Ti 10M% I.) Ti:0.12 phase m _ _ 4 Co 20M%, Co:0.28 single I.) PVA 1.00 1.14 1.10 700/24 4.16 91 30.1 Ti 20M% Ti:0.21 phase ko 0 co -Ni 10M%, Ni:0.12 single 1 0 PVA 1.00 1.05 1.03 700/24 12.04 94 26.4 w Ti 10M% Ti:0.11 phase I.) _ 6 Fe 10M%, Fe:0.12 single PVA 1.00 1.04 1.04 700/24 3.46 78 27.5 Ti 10M% Ti:0.12 phase -7 Co 10M%, Co:0.12 single starch 1.00 1.02 1.02 700/24 3.18 120 47.8 . Ti 10M% Ti:0.11 phase 8 granu- Co:0.13 Co 10M%, singe lated 1.00 1.02 1.02 Ti:0.11 700/24 3.35 111 48.9 Ti 10M% phase sugar 9 Co 5M%, Co:0.05 single PVA 1.00 0.92 0.97 700/24 3.20 108 27.4 Ni 5M% Ni:0.04 phase Co 5M%, Co:0.05 single PVA 1.00 0.91 0.90 700/24 12.91 115 30.1 Fe 5M% Fe:0.04 phase comp. 1 - 700/24 0.02 single none none 1.00 0.93 0.94 785 1.8 - phase exam--0.02 L13PO4 +
none none 1.00 0.93 0.92 202 10.6 pies -LiMnPO4 3 - 700/24 3.96 single none PVA 1.00 0.93 0.93 223 33.1 - phase 4 Ti:0.10 700/24 3.46 single Ti 10M% starch 1.00 0.86 0.90 171 52.1 - phase _ Co:0.14 700/24 3.56 single Co 10M% starch 1.00 1.05 1.03 241 47.1 - phase , - _ 6 Fe 10M% starch 1.00 0.95 0.96 Fe:0.14 700/24 3.28 single 48.2 n -phase -1.) m 1.) w m M% in the tables indicates mol%.
N
I tO
IV
cm 0 o 0 co u.) 1.)
discharge substituting carbon-containing capacity metal material mAh/g 1 Co 5M%, Ti 5M% none 46 2 Co 5M%, Ti 5M% PVA 66 3 Co 10M%, Ti 10M% PVA 90 4 Co 20M%, Ti 20M% PVA 50 examples 5 Ni 10M%, Ti 10M% PVA 72 6 Fe 10M%, Ti 10M% PVA 99 7 Co 10M%, Ti 10M% starch 79 8 Co 10M%, Ti 10M% granulated sugar 85 9 Co 5M%, Ni 5M% PVA 16 Co 5M%, Fe 5M% PVA 42 1 none none 7 not 2 none none compar-measured ative 3 none PVA 35 examples 4 Ti 10M% starch 43 5 Co 10M% starch 5 6 Fe 10M% starch 11
of a 1.0 mol/L aqueous solution of Fe2(SO4)2 and 0.031 L of a 1.0 mol/L aqueous solution of Ti(SO4)2 with thorough stirring.
0.166 L of a 2.04 mol/L aqueous solution of 1131304 was then added dropwise at 40 C and over 30 minutes and mixing was carried out for an additional 30 minutes. 0.406 L of a 2.5 mol/L aqueous LiOH solution was then added dropwise over 30 minutes, followed by heating to 100 C and stirring for 1 hour.
The resulting coprecipitated product was filtered off, washed with 1 L deionized water, and dried for 12 hours in a 140 C
oven. To 15 g of the resulting sample were added 3.07 g glucose and 30 mL deionized water with thorough mixing using a planetary ball mill. This sample was dried for 12 hours in a 140 C oven. The resulting mixture was ground with a mortar.
It was then subjected to pre-calcination for 12 hours at 350 C
and main calcination for 24 hours at 650 C under an N2 blanket.
The resulting sample was analyzed as in Example 1. The results from the compositional analysis and x-ray diffraction measurement, the measured specific surface area, and the average particle diameter are shown in Table 3; the SEM
photograph is shown in Fig. 36.
Discharge was carried out in the potential range of 2000 to 4500 mV at a rate of 1 C (approximately 0.9 mA/cm2). The potential (mV) and total capacity per unit gram of the positive electrode active material (mAh/g) recorded during the first charge-discharge cycle were designated as the initial charge-discharge characteristics. Otherwise, constant-current charge-discharge testing was carried out as in Example 1. The initial charge-discharge characteristics .are shown in Table 4 and Fig. 37.
of a 1.0 mol/L aqueous solution of Fe2(904)2 and 0.034 L of a 1.0 mol/L aqueous solution of Ti(SO4)2 with thorough stirring.
0.166 L of a 2.04 mol/L aqueous solution of H3PO4 was then added dropwise at 40 C and over 30 minutes and mixing was carried out for an additional 30 minutes. 0.406 L of a 2.5 mol/L aqueous LiOH solution was then added dropwise over 30 minutes, followed by heating to 100 C and stirring for 1 hour.
The resulting coprecipitated product was filtered off, washed with 1 L deionized water, and dried for 12 hours in a 140 C
oven. To 15 g of the resulting sample were added 3.07 g glucose and 30 mL deionized water with thorough mixing using a planetary ball mill. This sample was dried for 12 hours in a 140 C oven. The resulting mixture was ground with a mortar.
It was then subjected to pre-calcination for 12 hours at 350 C
and main calcination for 24 hours at 700 C under an N2 blanket.
The resulting sample was analyzed as in Example 1. The results from the compositional analysis and x-ray diffraction measurement, the measured specific surface area, and the average particle diameter are shown in Table 3; the SEM
photograph is shown in Fig. 38.
of a 1.0 mol/L aqueous solution of Fe2(SO4)2 and 0.060 L of a 1.0 mol/L aqueous solution of Ti(SO4)2 with thorough stirring.
0.166 L of a 2.04 mol/L aqueous solution of H3PO4 was then added dropwise at 40 C and over 30 minutes and mixing was carried out for an additional 30 minutes. 0.406 L of a 2.5 mol/L aqueous LiOH solution was then added dropwise over 30 minutes, followed by heating to 100 C and stirring for 1 hour.
The resulting coprecipitated product was filtered off, washed with 1 L deionized water, and dried for 12 hours in a 140 C
oven. To 15 g of the resulting sample were added 3.07 g glucose and 30 mL deionized water with thorough mixing using a planetary ball mill. This sample was dried for 12 hours in a 140 C oven. The resulting mixture was ground with a mortar.
It was then subjected to pre-calcination for 12 hours at 350 C
and main calcination for 24 hours at 700 C under an N2 blanket.
The resulting sample was analyzed as in Example 1. The results from the compositional analysis and x-ray diffraction measurement, the measured specific surface area, and the average particle diameter are shown in Table 3; the SEM
photograph is shown in Fig. 40.
of a 1.0 mol/L aqueous solution of Fe2(SO4)2 and 0.034 L of a 1.0 mol/L aqueous solution of Ti(SO4)2 with thorough stirring.
0.166 L of a 2.04 mol/L aqueous solution of H3PO4 was then added dropwise at 40 C and over 30 minutes and mixing was carried out for an additional 30 minutes. 0.406 L of a 2.5 mol/L aqueous LiOH solution was then added dropwise over 30 minutes, followed by heating to 100 C and stirring for 1 hour.
The resulting coprecipitated product was filtered off, washed with 1 L deionized water, and dried for 12 hours in a 140 C
oven. To 15 g of the resulting sample were added 1.56 g cellulose acetate and 25 mL acetone with thorough mixing using a planetary ball mill. This sample was dried for 12 hours in a 140 C oven. The resulting mixture was ground with a mortar.
It was then subjected to pre-calcination for 12 hours at 350 C
and main calcination for 24 hours at 650 C under an N2 blanket.
The resulting sample was analyzed as in Example 1. The results from the compositional analysis and x-ray diffraction measurement, the measured specific surface area, and the average particle diameter are shown in Table 3; the SEM
photograph is shown in Fig. 42.
photograph is shown in Fig. 44.
,
Table 3. Composition and properties of the products calcina-carbon- fluorescent x-ray specific substi-tion carbon particle contain- analysis (mol% versus Mn) surface tuting condi-content XRD diameter ing area metal Mn P Li %
tions % nm material m2/g C/hr exam- Fe 9M%, Fe:0.10 single 11 glucose 1.00 1.09 1.22 650/24 5.01 93 29.6 Ti 9M% Ti:0.10 phase 0 pies Fe 10M%, Fe:0.12 single 0 1., 12 glucose 1.00 1.04 1.33 700/24 4.90 82 35.9 m Ti 10M% Ti:0.13 phase w , m 1., Fe 15M%, Fe:0.21 single 1 ko 13 glucose 1.00 1.22 1.45 700/24 5.77 80 39.6 Ti 15M% Ti:0.22 phase cr, 4, w Fe 10M%, cellulose Fe:0.13 single 1 1 14 1.00 1.09 1.28 650/24 2.09 98 18.0 0 0.
Ti 10M% acetate Ti:0.13 phase 4, . _ -.3 Fe 10M%, pyro- Fe:0.13 single 15 Ti 10M% mellitic 1.00 1.09 1.28 Ti:0.13 650/24 3.09 phase 104 16.1 , acid
discharge substituting carbon-containing capacity metal material mAh/g 11 Fe 9M%, Ti 9M% glucose 113 12 Fe 10M%, Ti 10M% glucose 115 examples 13 Fe 15M%, Ti 15M% glucose 105 14 Fe 10M%, Ti 10M% cellulose acetate 114 15 Fe 10M%, Ti 10M% pyromellitic acid 114 INDUSTRIAL APPLICABILITY
Claims (9)
and carbon on the surface of the olivine-type lithium manganese phosphate compound particles in an amount no greater than 20 weight%
wherein said positive electrode active material has a particle diameter of 10 to 500 nm.
mixing a pre-calcination precursor for an olivine-type lithium manganese phosphate compound represented by the following general formula (2) Li x Mn y M1z M2w PO4 (2), wherein 0 < x < 2, 0 < y < 1, 0 < z < 0.2, 0 < w < 0.2, M1 is at least one divalent metal element selected from the group consisting of Co, Ni, and Fe, and M2 is Ti, with a carbon source in an amount no greater than 20 weight%; and calcining the obtained mixture under an inert gas atmosphere or a reducing atmosphere, wherein the pre-calcination precursor for the olivine-type lithium manganese phosphate compound is a coprecipitated product obtained by a step comprising: mixing an aqueous manganese salt solution, an aqueous solution containing a salt of at least one metal selected from the group consisting of Co, Ni, Fe, and Ti, an aqueous H3PO4 solution, and an aqueous LiOH
solution; and producing said coprecipitated product by holding the obtained mixed solution at 50 to 100°C.
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| CN101283465A (en) | 2008-10-08 |
| WO2007034821A1 (en) | 2007-03-29 |
| CA2623629A1 (en) | 2007-03-29 |
| EP1936721A4 (en) | 2011-08-31 |
| KR20080047537A (en) | 2008-05-29 |
| US20100148114A1 (en) | 2010-06-17 |
| JPWO2007034821A1 (en) | 2009-03-26 |
| KR101358515B1 (en) | 2014-02-05 |
| US7964118B2 (en) | 2011-06-21 |
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