Abstract: A preparation method of a composite cathode material is disclosed and includes steps of: (a) providing a nickel-manganese compound material, wherein the nickel-manganese compound material is NixMny(OH)2 or NixMnyO, x+y=1; (b) providing a solid electrolyte material, and mixing the nickel-manganese compound material and the solid electrolyte material in a mechanical mixing into a composite material, wherein the solid electrolyte material has a weight percentage relative to the nickel-manganese compound material, and the weight percentage is ranged from 0.2 wt. % to 1.0 wt. %; and (c) providing a lithium source, mixing the lithium source and the composite material, and sintering to form the composite cathode material, wherein the composite cathode material includes a core and a coating layer, the core is made of LiNi2xMn2yO4 and coated by the coating layer, and the coating layer is made of the solid electrolyte material.

Abstract: A high-voltage composite positive electrode material and manufacturing method thereof are disclosed. The high-voltage composite positive electrode material includes lithium nickel manganese oxide (LNMO) powders and lithium vanadium fluorophosphate (LVPF) powders. The LNMO powders have a first average particle diameter. A molar ratio of the LVPF powders to the LNMO powders is equal to or less than 0.5. The LVPF powders have a second average particle diameter. The second average particle diameter is less than one-tenth of the first average particle diameter, and the LVPF powders and the LNMO powders are mixed by a mechanically mixing method, so that the LVPF powders are coated on the surfaces of the LNMO powders to form the high-voltage composite positive electrode material.

Abstract: A preparation method of a lithium iron phosphate cathode material includes steps of (a) providing a phosphoric acid, an iron powder, a carbon source, wherein the phosphoric acid and the iron powder are reacted to produce a first product, and the first product is amorphous iron phosphate with chemical formula of a-FePO4·xH2O (x>0); (b) providing a lithium salt mixture, wherein the lithium salt mixture includes a lithium hydroxide and a lithium carbonate; (c) grinding and mixing the first product, the carbon source, and the lithium salt mixture; (d) calcining the first product and the lithium salt mixture to produce a precursor, wherein the precursor has a formula of Fe3(PO4)2·8H2O+Li3PO4; and (e) calcining the precursor and the carbon source to obtain the lithium iron phosphate cathode material.

Abstract: A recycling and reworking method of a lithium iron phosphate cathode material is disclosed and includes steps of: (a) providing a lithium iron phosphate recycled material; (b) oxidizing the lithium iron phosphate recycled material in an atmosphere at an oxidation temperature ranged from 300° C. to 400° C. for 1 hour to 5 hours to form a raw material powder composed of LiFePO4, Fe7(PO4)6, Fe2O3 and a residual carbon ranged from 0.07 wt. % to 0.6 wt. %; (c) grinding the raw material powder; (d) adjusting the composition of the raw material powder to form a precursor, which has the molar ratio of Li:P=0.99˜1.05:1, and the molar ratio of Fe:P=0.98˜1.02:1, wherein a carbon source is added; and (e) heat-treating the precursor in an inert gas at a sintering temperature ranged from 500° C. to 800° C. for 8 hours to 12 hours to form a lithium iron phosphate regenerated material.

Abstract: A cathode material and a preparation thereof are disclosed. The cathode material includes a core and a coating layer coated on the core. The core is formed by a ternary material having a composition of Li[NixCoyMnz]O2, wherein x+y+z=1, 0.8<x<1, 0<y<0.2, and 0<z<0.2. The coating layer is formed by an iron-phosphate compound material and includes a plurality of first particles aggregated. With high nickel content in the core, the cathode material with high energy density and low cost is realized. Since the iron-phosphate compound material has high-rate capability, the coating layer formed thereby further improves the rate capability of the cathode material.

Abstract: A dual-cation metal battery and a charging and discharging method thereof are disclosed to reduce the cost of materials, maintain the long-term service life and provide multiple varied applications. The dual-cation metal battery includes a positive electrode, a negative electrode, an electrolyte solution and a separator. The positive electrode includes a positive-electrode material selected from the group consisting of heterosite (FePO4), lithium iron phosphate (LiFePO4) and LixNa1-xFePO4, and 0<x<1. The negative electrode includes a metal mixture consisting of lithium metal and sodium metal, and the weight ratio of lithium metal to sodium metal is 1:3. The electrolyte solution is disposed between the positive electrode and the negative electrode. The separator is disposed in the electrolyte solution, and the positive electrode and the negative electrode are separated from each other by the separator.

Abstract: A preparation method of a cathode material for a secondary battery is provided. First, a lithium metal phosphate material and a first conductive carbon are provided. The lithium metal phosphate material is made of a plurality of secondary particles. Each of the secondary particles is formed by the aggregation of a plurality of primary particles. An interparticle space is formed between the plurality of primary particles. Next, the lithium metal phosphate material and the first conductive carbon are mixed by a mechanical method, and a composite material is prepared. The first conductive carbon is uniformly arranged in the interparticle space. After that, a second conductive carbon, a binder and a solvent are provided. Finally, the composite material, the second conductive carbon, the binder and the solvent are mixed, and a cathode material for preparing a positive plate is prepared.

Abstract: A carbon-coated cathode material and a preparation method thereof. The carbon-coated cathode material includes a lithium metal phosphate particle and a carbon coating layer. The carbon coating layer is coated on the lithium metal phosphate particle. The carbon coating layer is formed by a first heat treatment and a second heat treatment. A first carbon source is added in the first heat treatment, and a second carbon source is added in the second heat treatment. The first carbon source has a first weight percentage relative to the lithium metal phosphate particle. The second carbon source has a second weight percentage relative to the lithium metal phosphate particle. The first weight percentage of the first carbon source is equal to or less than the second weight percentage of the second carbon source.

Abstract: A preparation method of a cathode material for a secondary battery is provided. First, a lithium metal phosphate material and a first conductive carbon are provided. The lithium metal phosphate material is made of a plurality of secondary particles. Each of the secondary particles is formed by the aggregation of a plurality of primary particles. An interparticle space is formed between the plurality of primary particles. Next, the lithium metal phosphate material and the first conductive carbon are mixed by a mechanical method, and a composite material is prepared. The first conductive carbon is uniformly arranged in the interparticle space. After that, a second conductive carbon, a binder and a solvent are provided. Finally, the composite material, the second conductive carbon, the binder and the solvent are mixed, and a cathode material for preparing a positive plate is prepared.

Abstract: A preparation method of battery composite material includes steps of providing a manganese-contained compound, phosphoric acid, a lithium-contained compound, a carbon source, and deionized water; processing a reaction of the manganese-contained compound, the phosphoric acid, and a portion of the deionized water to produce a first product; placing the first product at a first temperature for at least a first time period to produce a first precursor, wherein the chemical formula of the first precursor is written by Mn5(HPO4)2(PO4)2(H2O)4; and processing a reaction of at least the first precursor, the lithium-contained compound, and another portion of the deionized water, adding the carbon source, and then calcining to produce battery composite material. Therefore, the preparation time is shortened, the energy consuming is reduced, the phase forming of the precursor is more stable, and the advantages of reducing the cost of preparation and enhancing the quality of products are achieved.

Abstract: A preparation method of a lithium nickel manganese oxide cathode material of a battery includes steps of providing a nickel compound, a manganese compound, a first quantity of lithium compound, a second quantity of lithium compound and a compound containing metallic ions, mixing the nickel compound, the first quantity of lithium compound, dispersant and deionized water to produce first product solution, adding the manganese compound into the first product solution and mixing to produce second product solution, performing a first grinding to produce first precursor solution, mixing the second quantity of lithium compound, the compound containing the metallic ions and the first precursor solution, then performing a second grinding to produce second precursor solution, and calcining the second precursor solution to produce the lithium nickel manganese oxide cathode material of the battery, the formula of which is written by Li1.0+xNi0.5Mn1.5MyO4. Therefore, the activation energy of reaction can be reduced.

Abstract: A preparation method of a battery composite material includes steps of providing phosphoric acid, a first metal source, a second metal source and water, processing a reaction of the first metal source, the second metal source, the phosphoric acid and the water to produce a first product, calcining the first product to produce a first precursor or a second precursor, among which each of the first precursor and the second precursor is a solid-solution containing first metal and second metal, and processing a reaction of the first precursor or the second precursor, and a first reactant to obtain a reaction mixture, and then calcining the reaction mixture to produce the battery composite material. As a result, the battery product has two stable charging and discharging platforms, such that the present invention achieves the advantages of enhancing the stability and the electric performance.

Abstract: A preparation method of a battery composite material includes steps of providing phosphoric acid, manganese carbonate, water and a first reactant; processing a reaction of the phosphoric acid, the manganese carbonate and the water to produce a first product; calcining the first product to produce a precursor, which is written by Mn2P2O7; processing a reaction of the precursor and at least the first reactant to get a reaction mixture, and then calcining the reaction mixture to produce the battery composite material. As a result, the present invention achieves the advantages of reducing the times of the reduction-oxidation reaction, so that the stability of the processes is enhanced, and the difficulty of the processes is reduced.

Abstract: A preparation method of battery composite material includes steps of providing a manganese-contained compound, phosphoric acid, a lithium-contained compound, a carbon source, and deionized water; processing a reaction of the manganese-contained compound, the phosphoric acid, and a portion of the deionized water to produce a first product; placing the first product at a first temperature for at least a first time period to produce a first precursor, wherein the chemical formula of the first precursor is written by Mn5(HPO4)2(PO4)2(H2O)4; and processing a reaction of at least the first precursor, the lithium-contained compound, and another portion of the deionized water, adding the carbon source, and then calcining to produce battery composite material. Therefore, the preparation time is shortened, the energy consuming is reduced, the phase forming of the precursor is more stable, and the advantages of reducing the cost of preparation and enhancing the quality of products are achieved.

Abstract: A cathode material with oxygen vacancy is provided. The cathode material includes a lithium metal phosphate compound having a general formula LiMPO4-Z, wherein M represents at least one of a first-row transition metal, and 0.001?z?0.05.

Abstract: A method of preparing a lithium nickel manganese oxide cathode material comprises the following steps of providing a precursor material, the precursor material comprises a lithium compound, a nickel compound and a manganese compound, mixing and grinding the lithium compound, the nickel compound and the manganese compound to from a cathode material precursor having a specific span value or a specific value of 90 percent particle size volume distribution (D90), (wherein the specific span value is greater than or equal to 1.0 ?m and lesser than or equal to 2.0 ?m, the specific value of 90 percent particle size volume distribution is greater than or equal to 0.3 ?m and lesser than or equal to 0.4 ?m), and processing a thermal treatment to the cathode material precursor to form the lithium nickel manganese oxide cathode material.

Abstract: A preparation method of a lithium nickel manganese oxide cathode material of a battery includes steps of providing a nickel compound, a manganese compound, a first quantity of lithium compound, a second quantity of lithium compound and a compound containing metallic ions, mixing the nickel compound, the first quantity of lithium compound, dispersant and deionized water to produce first product solution, adding the manganese compound into the first product solution and mixing to produce second product solution, performing a first grinding to produce first precursor solution, mixing the second quantity of lithium compound, the compound containing the metallic ions and the first precursor solution, then performing a second grinding to produce second precursor solution, and calcining the second precursor solution to produce the lithium nickel manganese oxide cathode material of the battery, the formula of which is written by Li1.0+xNi0.5Mn1.5MyO4. Therefore, the activation energy of reaction can be reduced.

Abstract: A cathode material with oxygen vacancy is provided. The cathode material includes a lithium metal phosphate compound having a general formula LiMPO4?z, wherein M represents at least one of a first-row transition metal, and 0.001?z?0.05.

Abstract: A cathode material with oxygen vacancy is provided. The cathode material includes a lithium metal phosphate compound having a general formula LiMPO4-Z, wherein M represents at least one of a first-row transition metal, and 0.001?z?0.05.

Abstract: A preparation method of a battery composite material includes steps of providing phosphoric acid, iron powder, a carbon source and a first reactant, processing a reaction of the phosphoric acid and the iron powder to produce a first product, calcining the first product to produce a precursor, among which the formula of the precursor is written by Fe7(PO4)6, and processing a reaction of the precursor, the carbon source and the first reactant to get a reaction mixture and calcining the reaction mixture to produce the battery composite material. As a result, the present invention achieves the advantages of reducing grind time of fabricating processes, so that the prime cost, the time cost, and the difficulty of fabricating are reduced.