Battery negative electrode active material based on quinone structure and preparation method and application thereof

A technology of battery negative electrode and active material, applied in the field of materials, can solve the problems of low Coulombic efficiency, poor cycle performance, hidden safety hazards, etc.

Active Publication Date: 2015-07-22
INST OF PHYSICS - CHINESE ACAD OF SCI
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

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Problems solved by technology

[0004] Among carbon anode materials, hard carbon has the largest degree of disorder in the carbon layer, the best sodium storage effect, and a specific capacity of 200-300mAh / g (J Electrochem Soc, 2001, 148, A803), but due to its low sodium storage potential and high rate Poor performance, during fast charging or overcharging, sodium may deposit on the surface to form dendrites, causing safety hazards; alloy materials such as tin, phosphorus and lead, etc., although have high sodium storage capacity, but the first week efficiency is low , poor cycle performance (J Power Sources, 2013, 225, 316-322), which is mainly due to the large volume deformation of the alloy during the process of intercalation and deintercalation of sodium, which leads to structural damage and a rapid decline in sodium storage performance (Angew Chem, 2013, 125, 4731-4734); Na 2 Ti 3 o 7 Such oxide negative electrode materials have poor conductivity, low sodium storage potential, low coulombic efficiency in the first week, and cycle stability needs to be improved (Adv Energy Mater, 2013, 3, 1186-1194); while NaTi 2 (PO 4 ) 3 Although the representative phosphate negative electrode material has high cycle stability, its high sodium storage potential leads to a decrease in energy density (J Electrochem Soc, 2011, 158, A1067-1070); organic negative electrode materials, such as sodium terephthalate A typical representative (Adv Energy Mater, 2012, 2, 962-965), has the advantages of high specific capacity and high cycle stability, but due to the low sodium storage potential, the electrolyte solution is reduced and decomposed on the electrode surface, resulting in an efficiency of only 60 in the first week. % or so, difficult to practical application

Method used

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  • Battery negative electrode active material based on quinone structure and preparation method and application thereof
  • Battery negative electrode active material based on quinone structure and preparation method and application thereof
  • Battery negative electrode active material based on quinone structure and preparation method and application thereof

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Embodiment 1

[0067] Embodiment 1 of the present invention provides a battery negative electrode material based on a quinone structure, including a quinone compound with a quinone structure as an electrochemical redox reaction site;

[0068] Among them, the quinone compounds include any one of benzoquinone sodium salt derivatives, anthraquinone sodium salt derivatives or naphthoquinone sodium salt derivatives; benzoquinone sodium salt derivatives, anthraquinone sodium salt derivatives or naphthoquinone sodium salt derivatives Derivatives have the following groups -ONa, -SO 3 At least one of Na or -COONa.

[0069] Specifically, the structure of the benzoquinone sodium salt derivative is shown in general formula (I):

[0070]

[0071] General formula (I)

[0072] Among them, the group R 1 , R 2 , R 3 , R 4 At least one group in is -ONa, -SO 3 One of Na or -COONa, other groups include -ONa, -SO 3 Na, -COONa, -H, -CH 3 , -NH 2 、-OCH 3 , -Cl, -Br or -F in one or more.

[0073] The...

Embodiment 2

[0083] This embodiment provides a method for preparing a battery negative electrode active material based on a quinone structure, specifically an aqueous solution method, such as figure 1 shown, including:

[0084] Step 101, dissolving the required stoichiometric 101wt% to 110wt% sodium hydroxide and the required stoichiometric quinone compound in deionized water in proportion to form a mixed solution;

[0085] Wherein, the quinone compound is specifically one of hydroxyquinone compounds, carboxylic acid quinone compounds or sulfonic acid quinone compounds.

[0086] Step 102, evaporating the mixed solution to dryness in an air atmosphere at 100°C;

[0087] Step 103, after ultrasonic cleaning with ethanol to remove excess sodium hydroxide, drying and grinding to obtain powder;

[0088] In step 104, the powder is placed in a vacuum oven, dried at 100° C. for 8 hours, and then ground to obtain the negative electrode active material of the battery.

[0089] The preparation meth...

Embodiment 3

[0091] This embodiment provides a method for preparing battery negative electrode active materials based on quinone structure, specifically spray drying method, such as figure 2 shown, including:

[0092] Step 201, dissolving the required stoichiometric 101wt%-110wt% sodium hydroxide and the required stoichiometric quinone compound in deionized water in proportion to form a mixed solution;

[0093] Wherein, the quinone compound is specifically one of hydroxyquinone compounds, carboxylic acid quinone compounds or sulfonic acid quinone compounds.

[0094] Step 202, spray drying the mixed solution;

[0095] Step 203, after ultrasonic cleaning with ethanol to remove excess sodium hydroxide, drying and grinding to obtain powder;

[0096] In step 204, the powder is placed in a vacuum oven, dried at 100° C. for 8 hours, and then ground to obtain the battery negative electrode active material.

[0097]The preparation method of the negative electrode active material of the battery ...

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Abstract

The invention discloses a battery negative electrode active material based on a quinone structure, and a preparation method and an application of the battery negative electrode active material. The battery negative electrode active material comprises a quinone compound taking the quinone structure as an electrochemical oxidation-reduction reaction site, wherein the quinone compound comprises any one of a benzoquinone sodium salt derivate, an anthraquinone sodium salt derivate, or a naphthoquinone sodium salt derivate. The benzoquinone sodium salt derivate, the anthraquinone sodium salt derivate, or the naphthoquinone sodium salt derivate comprises at least one of the following groups of -ONa, -SO3Na, or -COONa.

Description

technical field [0001] The invention relates to the field of material technology, in particular to a battery negative electrode active material based on a quinone structure and a preparation method and application thereof. Background technique [0002] New energy sources such as solar energy and wind energy have the advantages of being renewable and environmentally friendly, but due to their instability, energy conversion and storage devices are required to improve reliability and utilization when they are connected to the grid. Chemical power sources are one of the most promising energy storage systems, among which lithium-ion batteries have been widely used in portable electronics and electric vehicles due to their high energy density and high voltage. However, the limited reserves of lithium resources and the high cost of purification limit its large-scale use. [0003] Sodium is in the same family as lithium, has similar chemical properties, is abundant in reserves, and...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): H01M4/60H01M10/054
CPCH01M4/137H01M4/1399H01M4/60H01M10/054H01M2004/027H01M2220/10Y02E60/10
Inventor 胡勇胜吴晓燕穆林沁丁月君陈立泉黄学杰
Owner INST OF PHYSICS - CHINESE ACAD OF SCI
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