Tailoring Sodium Carboxymethylcellulose Binders for High-Voltage LiCoO2 via Thermal Pulse Sintering

Polyvinylidene fluoride (PVDF), as the commercial cathode binder for lithium-ion batteries, presents several practical challenges, including insufficient conductivity, weak adhesion to active materials, and the use of toxic N-methylpyrrolidone for slurry preparation. However, while most water-solubl...

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Published in:Angewandte Chemie International Edition 2025-02, p.e202423796
Main Authors: Chen, Shiming, Zhu, Hengyao, Li, Jiangxiao, Yin, Zu-Wei, Chen, Taowen, Yao, Xiangming, Zhao, Wenguang, Xue, Haoyu, Jiang, Xin, Li, Yongsheng, Ren, Hengyu, Chen, Jun, Li, Jun-Tao, Yang, Luyi, Pan, Feng
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creator Chen, Shiming
Zhu, Hengyao
Li, Jiangxiao
Yin, Zu-Wei
Chen, Taowen
Yao, Xiangming
Zhao, Wenguang
Xue, Haoyu
Jiang, Xin
Li, Yongsheng
Ren, Hengyu
Chen, Jun
Li, Jun-Tao
Yang, Luyi
Pan, Feng
description Polyvinylidene fluoride (PVDF), as the commercial cathode binder for lithium-ion batteries, presents several practical challenges, including insufficient conductivity, weak adhesion to active materials, and the use of toxic N-methylpyrrolidone for slurry preparation. However, while most water-soluble binders can address the aforementioned issues, they fail to meet the requirements of high-voltage cathodes. In this work, we innovatively employed a thermal pulse sintering strategy to modify carboxymethyl cellulose sodium (CMC), enabling their application in 4.6 V LiCoO2 (93% capacity retention after 200 cycles). This strategy facilitates the decomposition of electrochemically active carboxyl groups, leading to ring opening reactions that generate numerous ether linkages (-C-O-C-) without introducing undesirable side effects on LiCoO2. The resulting components form additional charge carrier (i.e., Li+ and e-) pathways on the cathode surface. Additionally, the heating process also promotes uniform coating of the binder on the surface of LiCoO2, creating a protective layer that inhibits interfacial side reactions. Through proposing a scalable and economic manufacturing technology of multifunctional binder, this work enlightens the avenues for practical high-energy-density batteries.Polyvinylidene fluoride (PVDF), as the commercial cathode binder for lithium-ion batteries, presents several practical challenges, including insufficient conductivity, weak adhesion to active materials, and the use of toxic N-methylpyrrolidone for slurry preparation. However, while most water-soluble binders can address the aforementioned issues, they fail to meet the requirements of high-voltage cathodes. In this work, we innovatively employed a thermal pulse sintering strategy to modify carboxymethyl cellulose sodium (CMC), enabling their application in 4.6 V LiCoO2 (93% capacity retention after 200 cycles). This strategy facilitates the decomposition of electrochemically active carboxyl groups, leading to ring opening reactions that generate numerous ether linkages (-C-O-C-) without introducing undesirable side effects on LiCoO2. The resulting components form additional charge carrier (i.e., Li+ and e-) pathways on the cathode surface. Additionally, the heating process also promotes uniform coating of the binder on the surface of LiCoO2, creating a protective layer that inhibits interfacial side reactions. Through proposing a scalable and economic manufacturing technology of multi
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However, while most water-soluble binders can address the aforementioned issues, they fail to meet the requirements of high-voltage cathodes. In this work, we innovatively employed a thermal pulse sintering strategy to modify carboxymethyl cellulose sodium (CMC), enabling their application in 4.6 V LiCoO2 (93% capacity retention after 200 cycles). This strategy facilitates the decomposition of electrochemically active carboxyl groups, leading to ring opening reactions that generate numerous ether linkages (-C-O-C-) without introducing undesirable side effects on LiCoO2. The resulting components form additional charge carrier (i.e., Li+ and e-) pathways on the cathode surface. Additionally, the heating process also promotes uniform coating of the binder on the surface of LiCoO2, creating a protective layer that inhibits interfacial side reactions. Through proposing a scalable and economic manufacturing technology of multifunctional binder, this work enlightens the avenues for practical high-energy-density batteries.Polyvinylidene fluoride (PVDF), as the commercial cathode binder for lithium-ion batteries, presents several practical challenges, including insufficient conductivity, weak adhesion to active materials, and the use of toxic N-methylpyrrolidone for slurry preparation. However, while most water-soluble binders can address the aforementioned issues, they fail to meet the requirements of high-voltage cathodes. In this work, we innovatively employed a thermal pulse sintering strategy to modify carboxymethyl cellulose sodium (CMC), enabling their application in 4.6 V LiCoO2 (93% capacity retention after 200 cycles). This strategy facilitates the decomposition of electrochemically active carboxyl groups, leading to ring opening reactions that generate numerous ether linkages (-C-O-C-) without introducing undesirable side effects on LiCoO2. The resulting components form additional charge carrier (i.e., Li+ and e-) pathways on the cathode surface. Additionally, the heating process also promotes uniform coating of the binder on the surface of LiCoO2, creating a protective layer that inhibits interfacial side reactions. 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However, while most water-soluble binders can address the aforementioned issues, they fail to meet the requirements of high-voltage cathodes. In this work, we innovatively employed a thermal pulse sintering strategy to modify carboxymethyl cellulose sodium (CMC), enabling their application in 4.6 V LiCoO2 (93% capacity retention after 200 cycles). This strategy facilitates the decomposition of electrochemically active carboxyl groups, leading to ring opening reactions that generate numerous ether linkages (-C-O-C-) without introducing undesirable side effects on LiCoO2. The resulting components form additional charge carrier (i.e., Li+ and e-) pathways on the cathode surface. Additionally, the heating process also promotes uniform coating of the binder on the surface of LiCoO2, creating a protective layer that inhibits interfacial side reactions. Through proposing a scalable and economic manufacturing technology of multifunctional binder, this work enlightens the avenues for practical high-energy-density batteries.Polyvinylidene fluoride (PVDF), as the commercial cathode binder for lithium-ion batteries, presents several practical challenges, including insufficient conductivity, weak adhesion to active materials, and the use of toxic N-methylpyrrolidone for slurry preparation. However, while most water-soluble binders can address the aforementioned issues, they fail to meet the requirements of high-voltage cathodes. In this work, we innovatively employed a thermal pulse sintering strategy to modify carboxymethyl cellulose sodium (CMC), enabling their application in 4.6 V LiCoO2 (93% capacity retention after 200 cycles). This strategy facilitates the decomposition of electrochemically active carboxyl groups, leading to ring opening reactions that generate numerous ether linkages (-C-O-C-) without introducing undesirable side effects on LiCoO2. The resulting components form additional charge carrier (i.e., Li+ and e-) pathways on the cathode surface. Additionally, the heating process also promotes uniform coating of the binder on the surface of LiCoO2, creating a protective layer that inhibits interfacial side reactions. 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However, while most water-soluble binders can address the aforementioned issues, they fail to meet the requirements of high-voltage cathodes. In this work, we innovatively employed a thermal pulse sintering strategy to modify carboxymethyl cellulose sodium (CMC), enabling their application in 4.6 V LiCoO2 (93% capacity retention after 200 cycles). This strategy facilitates the decomposition of electrochemically active carboxyl groups, leading to ring opening reactions that generate numerous ether linkages (-C-O-C-) without introducing undesirable side effects on LiCoO2. The resulting components form additional charge carrier (i.e., Li+ and e-) pathways on the cathode surface. Additionally, the heating process also promotes uniform coating of the binder on the surface of LiCoO2, creating a protective layer that inhibits interfacial side reactions. Through proposing a scalable and economic manufacturing technology of multifunctional binder, this work enlightens the avenues for practical high-energy-density batteries.Polyvinylidene fluoride (PVDF), as the commercial cathode binder for lithium-ion batteries, presents several practical challenges, including insufficient conductivity, weak adhesion to active materials, and the use of toxic N-methylpyrrolidone for slurry preparation. However, while most water-soluble binders can address the aforementioned issues, they fail to meet the requirements of high-voltage cathodes. In this work, we innovatively employed a thermal pulse sintering strategy to modify carboxymethyl cellulose sodium (CMC), enabling their application in 4.6 V LiCoO2 (93% capacity retention after 200 cycles). This strategy facilitates the decomposition of electrochemically active carboxyl groups, leading to ring opening reactions that generate numerous ether linkages (-C-O-C-) without introducing undesirable side effects on LiCoO2. The resulting components form additional charge carrier (i.e., Li+ and e-) pathways on the cathode surface. Additionally, the heating process also promotes uniform coating of the binder on the surface of LiCoO2, creating a protective layer that inhibits interfacial side reactions. Through proposing a scalable and economic manufacturing technology of multifunctional binder, this work enlightens the avenues for practical high-energy-density batteries.</abstract><doi>10.1002/anie.202423796</doi></addata></record>
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