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Sodium-magnesium-manganese-based layered oxide material having variable-valence anions, preparation method and use

A technology of oxides and anions, applied in the field of materials, to achieve the effects of high specific energy, simple material preparation, and high-quality specific capacity

Active Publication Date: 2019-11-26
CHINA ELECTRIC POWER RES INST +3
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

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Problems solved by technology

[0006] However, sodium-ion batteries are still in the research stage at present, and there is no commercial sodium-ion battery cathode material. Now researchers focus on the layered structure oxide cathode material Na x MO 2 (M represents 3d transition metal elements, which can contain one or more, such as Ti, V, Cr, Fe, Mn, Co, Ni, Cu, Nb, Ru, Mo, Zn, etc.)

Method used

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  • Sodium-magnesium-manganese-based layered oxide material having variable-valence anions, preparation method and use
  • Sodium-magnesium-manganese-based layered oxide material having variable-valence anions, preparation method and use
  • Sodium-magnesium-manganese-based layered oxide material having variable-valence anions, preparation method and use

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Embodiment 1

[0059] The embodiment of the present invention provides a sodium-magnesium-manganese-based layered oxide material with variable anion valence, a preparation method and an application. The layered oxide material is easy to prepare, and the contained elements sodium, magnesium and manganese are all non-toxic and safe elements, and are abundant in the earth's crust, so the manufacturing cost is low. The sodium-ion secondary battery using the sodium-magnesium-manganese-based layered oxide material of the present invention has simple material preparation, and it is found in the half-cell test that the material not only has higher mass specific capacity and specific energy, but the specific capacity is equal to that of ordinary sodium It is 1.5 to 2 times that of the positive electrode material of ion batteries, and has a good cycle life. It has great practical value and can be used in large-scale energy storage equipment for solar power generation, wind power generation, smart grid ...

Embodiment 2

[0067] This embodiment provides a method for preparing a sodium-magnesium-manganese-based layered oxide material, specifically a solid-phase method, such as figure 2 shown, including:

[0068] Step 201, mixing sodium carbonate with a stoichiometric amount of required sodium of 100wt% to 108wt% and required stoichiometric magnesium oxide / magnesium carbonate and manganese dioxide in proportion to form a precursor;

[0069] Step 202, using a ball milling method to uniformly mix the precursor to obtain a precursor powder;

[0070] Step 203, placing the precursor powder in a muffle furnace, and heat-treating it in an air atmosphere at 600° C. to 1000° C. for 2 to 24 hours;

[0071] Step 204, grinding the heat-treated precursor powder to obtain a sodium-magnesium-manganese-based layered oxide material.

[0072] The preparation method of the sodium-magnesium-manganese-based layered oxide material provided in this embodiment can be used to prepare the sodium-magnesium-manganese-bas...

Embodiment 3

[0074] This embodiment provides a preparation method of a sodium-magnesium-manganese-based layered oxide material, specifically a spray drying method, such as image 3 shown, including:

[0075] Step 301, mixing sodium carbonate with a stoichiometric amount of required sodium of 100wt% to 108wt% and required stoichiometric magnesium oxide / magnesium carbonate and manganese oxide in proportion to form a precursor;

[0076] Step 302, adding ethanol or water to the precursor and stirring evenly to form a slurry;

[0077] Step 303, spray-drying the slurry to obtain a precursor powder;

[0078] Step 304, placing the precursor powder in a muffle furnace, and heat-treating in an air atmosphere at 600° C. to 1000° C. for 2 to 24 hours;

[0079] Step 305, grinding the heat-treated precursor powder to obtain a sodium-magnesium-manganese-based layered oxide material.

[0080] The preparation method of the sodium-magnesium-manganese-based layered oxide material provided in this embodime...

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Abstract

The invention discloses a sodium-magnesium-manganese-based layered oxide material having variable-valence anions, a preparation method and a use. The material has a chemical formula of Naa[MgbMnc]O2+[beta], wherein a, b, c, and [beta] are the mole percentages of the corresponding elements respectively and satisfy a relationship of b + c = 1 and a + b + 4c = 2 * (2 + [beta]), wherein 0.5 <= a <= 0.85; 0.25 <= b <= 0.425; 0.575 <= c <= 0.75; and -0.02 <= [beta] <= 0.02. The layered oxide material has a space group of P63 / mmc or P63 / mcm or R-3m, and a corresponding structure of P2 phase or P3 phase. An anionic variable-valence layered oxide material is used as a positive electrode active material of a sodium ion secondary battery. When the material is charged in the first cycle, oxygen ions in a crystal lattice lose electrons, and have an average valence increasing from -2 to a valence state between -2 and -1. When the material is discharged in the first cycle, oxygen ions with high valences regain electrons, and as the discharge progresses, some manganese ions obtain electrons and have an average valence state changing from tetravalent to trivalent. From the second cycle, during thecharge and discharge processes, oxygen ions and manganese ions jointly participate in reversible electron gain and loss processes.

Description

technical field [0001] The invention relates to the field of material technology, in particular to a sodium-magnesium-manganese-based layered oxide material with variable anion valence, a preparation method and an application. Background technique [0002] With the development and progress of society, human beings have an increasing demand for energy. However, due to the depletion of traditional fossil energy such as coal, oil, and natural gas, coupled with the increasingly severe problems of urban environmental pollution and greenhouse effect, Its application is gradually restricted in many ways, so the development of sustainable clean energy has always been the direction of attention of all countries. However, in the process of converting wind energy, solar energy, and tidal energy into electrical energy, these renewable energy sources are greatly restricted by natural conditions, and have the characteristics of obvious time discontinuity and spatial distribution, which le...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): H01M4/48H01M4/505H01M10/0525
CPCH01M4/505H01M4/48H01M10/0525Y02E60/10Y02E60/16
Inventor 胡勇胜容晓晖杨凯高飞陈立泉
Owner CHINA ELECTRIC POWER RES INST
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