Abstract: Disclosed in the invention are a lithium-rich manganese-based positive electrode material, a preparation method therefor and an application thereof. The lithium-rich manganese-based positive electrode material comprises a lithium-rich manganese-based positive electrode material core and a shell coated on the surface of the core. The shell comprises a first coating and a second coating. The first coating comprises a composite oxide of Al, Zr, Ce and La and an n-type thermoelectric material. The second coating comprises a composite carbon material, a hydrogen-containing lithium titanium oxide compound and molybdenum disulfide. The lithium-rich manganese-based positive electrode material of the present application has excellent specific discharge capacity, rate capability and cycle stability, and has broad application prospects.

Abstract: Disclosed herein are a composite positive electrode material, a preparation method therefor, and an application in a zinc ion battery. The composite positive electrode material comprises: a sulfur-doped three-dimensional network structure conductive polymer/graphene/carbon nanotube composite carbon material, and vanadium tetrasulfide nanoparticles that are loaded on the surface of the composite carbon material; said surface comprises at least one among the outer surface of conductive polymer particles, the sheet-layer surface and interlayer of graphene, and the outer surface of carbon nanotubes.

Abstract: A nickel lithium ion battery positive electrode material having a concentration gradient, and a preparation method therefor. The material is a core-shell material having a concentration gradient, the core material is a material having a high content of nickel, and the shell material is a ternary material having a low content of nickel. The method comprises: synthesizing a material precursor having a high content of nickel by means of co-precipitation, co-precipitating a ternary material solution having a low content of nickel outside the material precursor having a high content of nickel, aging, washing, and drying to form a composite precursor in which the low nickel material coats the high nickel material, adding a lithium source, grinding, mixing, calcining, and cooling to prepare a high nickel lithium ion battery positive electrode material.

Abstract: A composite-coated lithium iron phosphate in a three-dimensional nanonetwork layered structure and a preparation method therefor, and a lithium ion battery, wherein a composite is prepared by compounding a conducting polymer, graphene and a carbon nano tube. The preparation method for the coated lithium iron phosphate comprises the following steps: doping the composite and anhydrous ferric phosphate in situ in the process of preparing the anhydrous ferric phosphate, serving as a lithium iron phosphate precursor, then mixing the composite in-situ doped anhydrous ferric phosphate, a lithium source, a traditional carbon material and a solvent to obtain slurry, spray drying the slurry, and calcining to obtain the composite-coated lithium iron phosphate in a three-dimensional nanonetwork layered structure. The preparation method is simple and has a wide raw material source, low cost and very broad practical application prospect.

Abstract: A composite-coated lithium iron phosphate in a three-dimensional nanonetwork layered structure and a preparation method therefor, and a lithium ion battery, wherein a composite is prepared by compounding a conducting polymer, graphene and a carbon nano tube. The preparation method for the coated lithium iron phosphate comprises the following steps: doping the composite and anhydrous ferric phosphate in situ in the process of preparing the anhydrous ferric phosphate, serving as a lithium iron phosphate precursor, then mixing the composite in-situ doped anhydrous ferric phosphate, a lithium source, a traditional carbon material and a solvent to obtain slurry, spray drying the slurry, and calcining to obtain the composite-coated lithium iron phosphate in a three-dimensional nanonetwork layered structure. The preparation method is simple and has a wide raw material source, low cost and very broad practical application prospect.

Abstract: A nickel lithium ion battery positive electrode material having a concentration gradient, and a preparation method therefor. The material is a core-shell material having a concentration gradient, the core material is a material having a high content of nickel, and the shell material is a ternary material having a low content of nickel. The method comprises: synthesizing a material precursor having a high content of nickel by means of co-precipitation, co-precipitating a ternary material solution having a low content of nickel outside the material precursor having a high content of nickel, aging, washing, and drying to form a composite precursor in which the low nickel material coats the high nickel material, adding a lithium source, grinding, mixing, calcining, and cooling to prepare a high nickel lithium ion battery positive electrode material.