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Perovskite oxide KTaO3 potassium ion battery negative electrode material by template synthesis and preparation method thereof

A perovskite oxide, battery negative electrode technology, applied in battery electrodes, secondary batteries, circuits, etc., can solve the problems of slow potassium ion migration, difficult particle electron conduction, material lattice transformation, etc., to reduce electron migration. The effect of resistance, increased contact area, and improved athletic ability

Inactive Publication Date: 2017-11-24
宁波吉电鑫新材料科技有限公司
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Problems solved by technology

However, it is still very difficult to take into account the rate performance and cycle capacity retention performance of the material.
The main reasons are as follows: 1. When the redox reaction occurs, the electrode material should have fast lithium ion intercalation and deintercalation and electronic conduction, that is, it should have good electronic conductivity and ion conductivity at the same time. Many negative electrode materials have high However, it is an electronic insulator, and some negative electrode materials are good electronic conductors, but the diffusion capacity of lithium ions is weak, which greatly increases the polarization of the battery; 2. Many electrode materials are intercalated with lithium ions and There is a large volume change during the deintercalation process, resulting in the breakage of electrode material particles and the loss of effective electrode materials during the cycle. The large volume change also brings about the transformation of the material lattice during the charging and discharging process to produce a second phase. seriously affect the performance of the battery
3. Lithium battery negative electrode material with conversion reaction mechanism, the electronic insulation of the reaction product lithium compound seriously affects the reversibility of the material
ABOs 3 When the alloy reaction is carried out, the oxide can react with two metals, which may produce alloy solid solutions in various phases. Due to the interaction of bimetals, it may also produce electrochemical characteristics that are completely different from those of single metals. Therefore, ABOs 3 Type oxides may become a high-performance potassium-ion battery anode material, which may provide close to or more than 300mAh.g -1 The specific capacity, the volume change of the material that potassium ions enter or exit is also small; however, the research and development of this material in potassium ion batteries is basically blank
And its main problem is: 1, ionic conductivity and electron conductivity are lower; 2, the product potassium oxide after conversion reaction is electronic insulator and its potassium ion diffusion activation energy is also higher, causes larger electrochemical polarization; 3. The synthesis temperature is high, which is easy to cause the growth and agglomeration of grains
[0014] In response to these problems, changing the shape of the material can alleviate these problems to a certain extent. For example, reducing the particle size of the material to the nanometer scale can reduce the diffusion path of potassium ions, shorten the diffusion time of potassium ions, and improve the kinetics of the material. Performance; too small a particle size can easily cause difficulties in electronic conduction between particles; the same agglomeration between particles or too large particles can easily cause electrolyte penetration difficulties between particles, slow migration of potassium ions, etc.

Method used

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  • Perovskite oxide KTaO3 potassium ion battery negative electrode material by template synthesis and preparation method thereof

Examples

Experimental program
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Effect test

Embodiment 1

[0021]Embodiment 1: Potassium nitrate and tantalum hydroxide are mixed according to the ratio of 1: 1 of the amount of substance, and the amount of substance added is citric acid 5 times of the amount of total metal ion substance and added with water and stirred evenly to form a total metal ion concentration of 1.0mol ·L -1 The initial aqueous solution; mix and dissolve 6g acrylamide / 100mL water volume of acrylamide and 1g N,N'-methylenebisacrylamide / 100mL water volume N,N'-methylenebisacrylamide and water, and the acrylamide in the solution The amount of the substance is 0.5 times the amount of the total metal ion substance in the initial aqueous solution; use a polytetrafluoroethylene stirring paddle to stir at a speed of 1500rpm for 5 minutes, then raise it to 75°C at a speed of 5°C / min and maintain the temperature until it becomes a jelly-like gel. Dry the formed gel in a low-temperature and high-vacuum environment. The drying process adopts the finished freeze dryer on t...

Embodiment 2

[0022] Embodiment 2: Potassium nitrate and tantalum hydroxide are mixed according to the ratio of 1:1 of the amount of substance, and the amount of substance added is citric acid which is 7 times of the amount of total metal ion substance and added with water and stirred evenly to form a total metal ion concentration of 1.5mol ·L -1 The initial aqueous solution; mix and dissolve 6g acrylamide / 100mL water volume of acrylamide and 1g N,N'-methylenebisacrylamide / 100mL water volume N,N'-methylenebisacrylamide and water, and the acrylamide in the solution The amount of the substance is 0.8 times the amount of the total metal ion substance in the initial aqueous solution; use a polytetrafluoroethylene stirring paddle to stir at a speed of 1800rpm for 10 minutes, then raise it to 80°C at a speed of 7°C / min and maintain the temperature until it becomes a jelly-like gel. Dry the formed gel in a low-temperature and high-vacuum environment. The drying process adopts the finished freeze ...

Embodiment 3

[0023] Embodiment 3: Potassium nitrate and tantalum hydroxide are mixed according to the ratio of 1: 1 of the amount of substance, and the amount of substance added is citric acid 10 times of the amount of total metal ion substance and added with water and stirred evenly to form a total metal ion concentration of 2.5mol ·L -1 The initial aqueous solution; mix and dissolve 6g acrylamide / 100mL water volume of acrylamide and 1g N,N'-methylenebisacrylamide / 100mL water volume N,N'-methylenebisacrylamide and water, and the acrylamide in the solution The amount of the substance is 1.2 times the amount of the total metal ion substance in the initial aqueous solution; use a polytetrafluoroethylene stirring paddle to stir at a speed of 2000rpm for 15 minutes, then raise it to 85°C at a speed of 10°C / min and maintain the temperature until it becomes a jelly-like gel. Dry the formed gel in a low-temperature and high-vacuum environment. The drying process adopts the finished freeze dryer ...

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Abstract

The invention relates to a perovskite oxide KTaO3 potassium ion battery negative electrode material by template synthesis and a preparation method thereof. The perovskite oxide KTaO3 potassium ion battery negative electrode material is characterized in that a continuous porous-morphology perovskite structure product with particle parts bonded to one another is formed by employing a continuous porous structure of gel as a template. By such morphology, the grain boundary resistance is favorably reduced, the moving capability of potassium ions in lattices is improved, a continuous electron transfer network is formed, the electron transfer resistance is reduced, the contact area with an electrolyte is expanded, and the transfer capability of the potassium ions in the electrolyte and the lattices and the oxidization-reduction reaction ratio are improved; and such structure also has certain structural rigidity, buffer is formed for volume deformation of a material during the charge-discharge process, so that the high-performance potassium ion battery negative electrode material is formed.

Description

technical field [0001] The invention relates to the technical field of a method for manufacturing a negative electrode material of a perovskite oxide composite potassium ion battery. Background technique [0002] Lithium-ion secondary batteries have the absolute advantages of high volume, weight-to-energy ratio, high voltage, low self-discharge rate, no memory effect, long cycle life, and high power density. Currently, the global mobile power market has an annual share of more than 30 billion US dollars and Gradually grow at a rate of more than 10%. Especially in recent years, with the gradual depletion of fossil energy, new energy sources such as solar energy, wind energy, and biomass energy have gradually become alternatives to traditional energy sources. Among them, wind energy and solar energy are intermittent, and a large amount of energy is used simultaneously to meet the needs of continuous power supply. Energy storage batteries; urban air quality problems caused by ...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): H01M4/485H01M10/054
CPCH01M4/485H01M10/054Y02E60/10
Inventor 水淼
Owner 宁波吉电鑫新材料科技有限公司
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