锂离子电池硅基负极新型黏结剂研究进展

doi:10.12028/j.issn.2095-4239.2018.0087

储能科学与技术 ›› 2018, Vol. 7 ›› Issue (6): 1203-1210.doi: 10.12028/j.issn.2095-4239.2018.0087

锂离子电池硅基负极新型黏结剂研究进展

梁大宇, 包婷婷, 夏昕, 杨茂萍, 李道聪

合肥国轩高科动力能源有限公司工程研究总院, 安徽合肥 230011

收稿日期:2018-06-08 修回日期:2018-08-02 出版日期:2018-11-01 发布日期:2018-08-28
通讯作者: 梁大宇(1988-),男,工程师,研究方向为锂离子动力电池,E-mail:liangdayu@gotion.com.cn。
作者简介:梁大宇(1988-),男,工程师,研究方向为锂离子动力电池,E-mail:liangdayu@gotion.com.cn。
基金资助:
国家重大专项（2016YFB0100306）。

Research progress of novel binders for silicon-based anode in lithium ion battery

LIANG Dayu, BAO Tingting, XIA Xin, YANG Maoping, LI Daocong

Institute of Engineering Research, Hefei Guoxuan High Technology Power Energy Company, Hefei 230011, Anhui, China

Received:2018-06-08 Revised:2018-08-02 Online:2018-11-01 Published:2018-08-28
Contact: 10.12028/j.issn.2095-4239.2018.0087

摘要/Abstract

摘要： 硅基材料由于具有超高的理论比容量，安全的嵌锂工作电位和廉价易得等诸多优点，是下一代高比能量电池体系最理想的负极材料。尽管硅基材料的研究已经进行很长时间，但是硅基材料嵌锂时巨大的体积膨胀，循环性能较差等问题一直难以得到有效解决。开发高性能硅基负极黏结剂是解决硅基材料应用问题的重要途径之一，具有“刚柔并济”结构特性的黏结剂分子能够有效抑制硅基材料结构膨胀粉化，保持电极导电网络的完整性，从而有效提升其循环性能。本文综述了硅基负极黏结剂的特性要求，新型硅基负极黏结剂的研究进展，并对该领域未来潜在的研究方向进行了展望：复合体系聚合物黏结剂的开发；特殊空间构型黏结剂的开发；新型导电黏结剂的开发；自支撑无黏结剂硅基负极的开发。

关键词: 锂离子电池, 硅基负极, 聚合物黏结剂, 循环性能

Abstract: Silicon based materials are the most ideal candidates for the next generation Li-ion battery with high specific energy density due to their excellent characteristics such as high theoretical specific capacity, safe lithium intercalation potential and low cost. Despite have been studied for a long time, silicon based anodes suffer from immense volume change and chronic capacity fading during cycling. The development of novel binders with high performance is an effective way to promote the commercial application of silicon-based anodes. The polymer binders with rigid and flexible properties at the same time can restrain pulverization of silicon based materials and maintain the integrity of electrode conductive network, thus improving the cycle performance of silicon based anodes effectively. In this paper, the characteristic requirement for binders in silicon-based anodes and the current research progress of some novel binders are reviewed. In addition, some potential research directions in this field have been presented, including the investigation of composite binders, the investigation of binders with special space structures, and the investigation of conductive binders; the investigation of self-supporting non-binder silicon based anode.

Key words: lithium ion battery, silicon based materials, polymer binder, cycling performance

中图分类号:

TM911

梁大宇, 包婷婷, 夏昕, 杨茂萍, 李道聪. 锂离子电池硅基负极新型黏结剂研究进展[J]. 储能科学与技术, 2018, 7(6): 1203-1210.

LIANG Dayu, BAO Tingting, XIA Xin, YANG Maoping, LI Daocong. Research progress of novel binders for silicon-based anode in lithium ion battery[J]. Energy Storage Science and Technology, 2018, 7(6): 1203-1210.

参考文献

[1] TARASCON J M, ARMAND M. Building better batteries[J]. Nature, 2008, 451:652-657.
[2] GOODENOUGH J B, PARK K S. The Li-ion rechargeable battery:A perspective[J]. Journal of the American Chemical Society, 2013, 1359 (4):1167-1176.
[3] LI J, DANIEL C, WOOD D L. Materials processing for lithium-ion batteries[J]. Journal of Power Sources, 2011, 196:2452-2460.
[4] KWON T W, CHOI J W, COSKUN A. The emerging era of supramolecular polymeric binders in silicon anodes[J]. Chemical Society Reviews, 2018, 47:2145-2164.
[5] HAN X, ZHANG Z Q, YOU R, et al. Capitalization of interfacial AlON interactions to achieve stable binder-free porous silicon/carbon anodes[J]. Journal of Materials Chemistry A, 2018, 6:7449-7456.
[6] LI D W, WANG Y K, HU J Z. et al. Role of polymeric binders on mechanical behavior and cracking resistance of silicon composite electrodes during electrochemical cycling[J]. Journal of Power Sources, 2018, 387:9-15.
[7] JUNG C H, CHOI J, KIM W S, et al. A nanopore-embedded graphitic carbon shell on silicon anode for high performance lithium ion batteries[J]. Journal of Materials Chemistry A, 2018, 6:8013-8020.
[8] DOSE W M, PIERNAS-MUNOZ M J, MARONI V A, et al. Capacity fade in high energy silicon-graphite electrodes for lithium-ion batteriess[J]. Chemical Communications, 2018, 54:3586-3589.
[9] MENDEZ J P, PONGA M, ORTIZ M. Diffusive molecular dynamics simulations of lithiation of silicon nanopillars[J]. Journal of the Mechanics and Physics of Solids, 2015, 115:123-141.
[10] JANG K H, HYUN Y, PARK Y H, et al. Synthesis of carbon nanofibers and silicon-carbon nanofiber composites on electroplated Co-Ni/C-fiber textiles for anode material of Li ion batteries[J]. Journal of Nanoscience and Nanotechnology, 2017, 17 (11):8500-8505.
[11] HOROWITZ Y, HAN H L, SOTO F A, et al. Fluoroethylene carbonate as a directing agent in amorphous silicon anodes:electrolyte interface structure probed by sum frequency vibrational spectroscopy and Ab initio molecular dynamics[J]. Nano Letters, 2018, 18:1145-1151.
[12] KARKAR Z, GUYOMARD D, ROUE L, et al. A comparative study of polyacrylic acid (PAA) and carboxymethyl cellulose (CMC) binders for Si-based electrodes[J]. Electrochimica Acta, 2017, 258:453-466.
[13] HAYSA K A, RUTHERA R E, KUKAYA A J, et al. What makes lithium substituted polyacrylic acid a better binder than polyacrylic acid for silicon-graphite composite anodes?[J]. Journal of Power Sources, 2018, 384:136-144.
[14] CHOI S, KWON T W, COSKUN A, et al. Highly elastic binders integrating polyrotaxanes for silicon microparticle anodes in lithium ion batteries[J]. Science, 2017, 357:279-283.
[15] LUO L, XU Y L, ZHANG H, et al. Comprehensive understanding of high polar polyacrylonitrile as an effective binder for Li-ion battery nano-Si anodes[J]. ACS Applied Materials & Interfaces, 2016, 8 (12):8154-8161.
[16] CHOI J, KIM K, JEONG J, et al. Highly adhesive and soluble copolyimide binder:improving the long-term cycle life of silicon anodes in lithium-ion batteries[J]. Applied Materials & Interfaces, 2015, 7:14851-14858.
[17] YOON T, CHAPMAN N, NGUYEN C C, et al. Electrochemical reactivity of polyimide and feasibility as a conductive binder for silicon negative electrodes[J]. Journal of Materials Science, 2017, 52:3613-3621
[18] YAO D H, YANG Y, DENG Y H, et al. Flexible polyimides through one-pot synthesis as water-soluble binders for silicon anodes in lithium ion batterie[J]. Journal of Power Sources, 2018, 379:26-32.
[19] LIU J, ZHANG Q, WU Z Y, et al. A high-performance alginate hydrogel binder for the Si/C anode of a Li-ion battery[J]. Chemical Communications, 2014, 50:6386-6389.
[20] GU Y Y, YANG S M, ZHU G B, et al. The effects of cross-linking cations on the electrochemical behavior of silicon anodes with alginate binder[J]. Electrochimica Acta, 2018, 269:405-414.
[21] BIE Y, YANG J, NULI Y, et al. Oxidized starch as a superior binder for silicon anodes in lithium-ion batteries[J]. RSC Advance, 2016, 6:97084-97088.
[22] KURUBAL R, DATTA M K, DAMODARAN K, et al. Guar gum:Structural and electrochemical characterization of natural polymer based binder for silicon-carbon composite rechargeable Li-ion battery anodes[J]. Journal of Power Sources, 2015, 298:331-340
[23] LIU D, ZHAO Y, TAN R, et al. Novel conductive binder for high-performance silicon anodes in lithium ion batteries[J]. Nano Energy, 2017, 36:206-212.
[24] ZHOU M, LI X L, WANG B, et al. High-performance silicon battery anodes enabled by engineering graphene assemblies Nano Letter, 2015, 15:6222-6228.

锂离子电池硅基负极新型黏结剂研究进展

Research progress of novel binders for silicon-based anode in lithium ion battery

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