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Low-voltage and large-capacity self-supporting potassium ion battery negative electrode and preparation and application thereof

A battery negative electrode and low voltage technology, applied in battery electrodes, negative electrodes, secondary batteries, etc., can solve problems such as difficulty in meeting battery production standards, high charging platforms, and low energy density of devices

Active Publication Date: 2019-12-06
JINAN UNIVERSITY
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

However, there are still many problems in the potassium storage characteristics of existing carbon materials. For example, when most carbon materials are used for potassium storage, the charging platform is relatively high, which makes the energy density of the device after matching into a full battery low.
In addition, the loading capacity of most of the existing anode materials for potassium-ion batteries is based on the loading capacity commonly used in the laboratory (-2 ), it is difficult to meet industrial standards for battery production
Finally, the conventional laboratory method for studying the anode materials of potassium ion batteries is to mix carbon materials, conductive agents, and binders in a ratio of 8:1:1 to form a slurry, coat it on the current collector, and then dry it. , these cumbersome methods will lead to the generation of pollutants and waste of resources caused by this method, as well as the decrease of the energy density of the electrode itself
At present, there are no relevant research and reports on low-voltage, high-capacity self-supporting potassium-ion battery anodes

Method used

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  • Low-voltage and large-capacity self-supporting potassium ion battery negative electrode and preparation and application thereof
  • Low-voltage and large-capacity self-supporting potassium ion battery negative electrode and preparation and application thereof
  • Low-voltage and large-capacity self-supporting potassium ion battery negative electrode and preparation and application thereof

Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0034] (1) Pretreatment of self-supporting structural carbon materials: the 10×10cm 2 The commercialized carbon fiber fabrics were ultrasonically cleaned for 10 minutes by immersion in absolute ethanol, chloroform, and toluene, and then dried in an oven after being taken out.

[0035] (2) Concentrated sulfuric acid: Concentrated perchloric acid = 0.2:1 to prepare a mixed strong acid, add the above-cleaned and dried commercial carbon fiber fabric to the mixed strong acid, and place it under magnetic stirring and constant temperature heating at 70°C for 36 hours.

[0036] (3) The carbon fiber fabric after the above treatment was placed in a muffle furnace and annealed at 400° C. for 1 hour, and the acidified carbon fiber fabric was obtained after cooling down.

[0037] Figure 1-2 They are the scanning electron micrographs of the commercialized carbon fiber fabrics before and after the acidification treatment in Example 1, respectively. It can be seen from the figure that the ...

Embodiment 2

[0041] (1) Pretreatment of self-supporting structural carbon materials: Mix 0.1g carbon nanotubes, 0.1g lecithin and 200ml deionized water, form carbon nanotube ink after ultrasonic vibration for 15min, and vacuum filter the above ink into 3× 3cm 2 film and dried in an oven.

[0042] (2) Concentrated nitric acid by volume: concentrated hydroiodic acid=2:1 to prepare a mixed strong acid, add the above-cleaned and dried carbon nanotube film to the mixed strong acid, and place it under magnetic stirring and constant temperature heating at 90°C Heating in medium for 48h.

[0043] (3) The carbon nanotube film after the above treatment was placed in a tube furnace, heated to 600° C. under a nitrogen protection atmosphere with a flow rate of 100 ssm and kept for 2 hours, and the acidified carbon nanotube film was obtained after cooling down.

[0044] Figure 5-6They are scanning electron micrographs of the commercialized carbon nanotube films before and after the acidification tre...

Embodiment 3

[0048] (1) Pretreatment of self-supporting structural carbon materials: the 5 × 5cm 2 The commercial graphite paper was soaked in 80% ethanol aqueous solution and ultrasonically cleaned for 10 min.

[0049] (2) Concentrated sulfuric acid by volume: concentrated nitric acid = 1:1 to prepare a mixed strong acid, add the mixed strong acid to the commercialized carbon fiber fabric that has been cleaned and dried above, and place it under magnetic stirring and heating at a constant temperature of 85°C for heating 24h.

[0050] (3) The commercialized graphite paper treated above was placed in a muffle furnace and annealed at 450° C. for 1 h, and the acidified graphite paper was obtained after cooling down.

[0051] Figure 9-10 They are scanning electron micrographs of the commercialized carbon nanotube films before and after the acidification treatment in Example 3, respectively. It can be seen from the figure that the acidification treatment increases the wrinkles on the electr...

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Abstract

The invention discloses a low-voltage and high-load self-supporting potassium ion battery negative electrode material and a preparation and application thereof. The preparation method comprises the following steps: preparing a mixed strong acid according to a volume ratio of a first strong acid to a second strong acid of 0.2-3: 1, adding a carbon material into the mixed strong acid, carrying out areaction for 1-72h at the temperature of 50-90 DEG C, and then carrying out cleaning and drying to obtain a treated carbon material; and finally, annealing the treated carbon material at the temperature of 300-1000 DEG C for 0.5-5 hours. According to the invention, the common commercial carbon material is subjected to simple acidification treatment, and oxygen-containing functional groups are introduced into the surface, thereby reducing the reaction energy barriers, facilitating the embedding and escaping of potassium ions into and from the surface of the carbon material, so that the specific capacity and the rate capability are improved, the low-voltage platform characteristic of the carbon material is fully embodied, the voltage window of a device is improved, and the preparation method has very important significance for designing a potassium ion battery with high energy density.

Description

technical field [0001] The invention belongs to the technical field of negative electrode materials for potassium ion batteries, and in particular relates to a low voltage, high capacity self-supporting negative electrode for potassium ion batteries and its preparation and application. Background technique [0002] With the increasing popularity of high-tech products such as electric vehicles and smartphones, large-scale energy storage technology and portable electronics are booming. However, what follows is that the energy storage part of the above products - the lithium-ion battery is facing tremendous pressure: first, the large-scale production and application of lithium-ion batteries have made the already insufficient lithium resources stretched; It is more expensive than other metal elements, which increases production costs; finally, the price of lithium resources fluctuates greatly, which is not conducive to stabilizing industrial production. Therefore, it is very ur...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): H01M4/587H01M10/054
CPCH01M4/587H01M10/054H01M2004/027Y02E60/10
Inventor 黎晋良麦文杰谢俊鹏李晓丹卓闻琛
Owner JINAN UNIVERSITY
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