中文
Earlier issues
Announcement
More
Progress in Chemistry 2009, Vol. 21 Issue (10): 2115-2122 Previous Articles   Next Articles

Special Issue: 锂离子电池

• Review •

Si-Based Composite Anode Materials for Lithium Ion Batteries

Chen Jingbo;  Zhao Hailei**;   He Jianchao;  Wang Mengwei   

  1. (School of Material Science and Engineering, University of Science and Technology Beijing, Beijing 100083, China)
  • Received: Revised: Online: Published:
  • Contact: Zhao Hailei E-mail:hlzhao@mater.ustb.edu.cn
PDF ( 2956 ) Cited
Export

EndNote

Ris

BibTeX

As a kind of promising anode material for lithium ion batteries, silicon-based materials have been attracted much attention. The poor cycling stability due to the huge volume change during lithiation and delithiation and the low initial coulombic efficiency are the critical problems that limit their commercial application. Nanocrystallization, alloying and carbon-coating are effective measures to solve these issues. This article reviews the progress in silicon/compound composites in which TiB2, TiN and TiC act as the matrices, silicon-metal composites including Fe-Si, Cu-Si and Ni-Si, and silicon/carbon composites. In respect of the research on silicon/carbon composites, emphasis is put on the preparation methods like pyrolysis, milling, milling-pyrolysis and chemical polymerization, and the carbon sources such as polypyrrole, polyvinylchloride(PVC), polyacrylonitrile(PAN), resorcinol-formaldehyde resin, citric acid and epoxy resin. In addition, the progress in Si/carbon nanotubes composite materials is also discussed.

Contents
1 Introduction
2 Si-compound composites
3 Si-metal composites
3.1 Si-Fe composites
3.2 Si-Cu composites
3.3 Si-Ni composites
4 Si/C composites
4.1 Si/C composites prepared by pyrolysis
4.2 Si/C composites prepared by ball-milling
4.3 Si/C composites prepared by ball-milling and pyrolysis
4.4 Si/C composites prepared by other methods
4.5 Si/carbon nanotubes
5 Conclusions

Key words: Si-based materials, anode materials, lithium ion batteries

CLC Number: 

[ 1 ]  Huggins R A. J . Power Sources , 1999 , 81 —82 : 13 —19
[ 2 ]  Netz A , Huggins R A. Solid State Ionics , 2004 , 175 : 215 —219
[ 3 ]  Moon T, Kim C , Park B. J . Power Sources , 2006 , 155 : 391 —394
[ 4 ]  Kim I , Blomgren G E , Kumta P N. J . Power Sources , 2004 , 130 :275 —280
[ 5 ]  Zhang XN , Pan GL , Li GR , et al . Solid State Ionics , 2007 , 178 :1107 —1112
[ 6 ]  Kim I S , Kumta P N , Blomgren G E. Electrochem. Solid-State Lett . , 2000 , 3 : 493 —496
[ 7 ]  Hanai K, Liu Y, Imanishi N , et al . J . Power Sources , 2005 , 146 :156 —160
[ 8 ]  Wu Y S , Lee Y H , Tsai Y L. J . Mater. Process Tech. , 2008 ,208 : 35 —41
[ 9 ]  Patel P , Kim I S , Kumta P N. Mat . Sci . Eng. B , 2005 , 116 :347 —352
[10 ]  EomJ Y, Park J W, Kwon H S , et al . J . Electrochem. Soc. ,2006 , 153 : A1678 —A1684
[11 ]  Rocka N L , Kumta P N. J . Power Sources , 2007 , 164 : 829 —838
[12 ]  任慢慢(Ren MM) , 周震(Zhou Z) , 高学平(Gao X P) 等. 化学进展(Progress in Chemistry) , 2008 , 20 : 771 —777
[13 ]  Dong H , Ai X P , Yang H X. Electrochem. Commun. , 2003 , 5 :952 —957
[14 ]  Dong H , Feng R X, Yang H X, et al . Electrochim. Acta , 2004 ,49 : 5217 —5222
[15 ]  Zuo P J , Yin G P , Zhao Jun , et al . Electrochim. Acta , 2006 , 52 :1527 —1531
[16 ]  Jayaprakash N , Kalaiselvi N , Doh C H. Intermetallics , 2007 , 15 :442 —450
[17 ]  Doh C H , Shin H M, Kim D H , et al . J . Alloys. Compd. , 2008 ,461 : 321 —325
[18 ]  NuLi Y, Wang B F , Yang J , et al . J . Power Sources , 2006 , 153 :371 —374
[19 ]  Kang YM, Park M S , Song M S , et al . J . Power Sources , 2006 ,162 : 1336 —1340
[20 ]  KimJ W, Ryu J H , Lee K T, et al . J . Power Sources , 2005 , 147 :227 —233
[21 ]  Khomenko V G, Barsukov V Z, Doninger J E , et al . J . Power Sources , 2007 , 165 : 598 —608
[22 ]  Kim I C , Byun D , Lee S , et al . Electrochim. Acta , 2006 , 52 :1532 —1537
[23 ]  Yoon S , Lee S I , Kim H , et al . J . Power Sources , 2006 , 161 :1319 —1323
[24 ]  Beaulieu L Y, Eberman K W, Turner R L , et al . Electrochem. Solid-State Lett . , 2001 , 4 : A137 —A140
[25 ]  Kang YM, Park M S , Lee J Y, et al . Carbon , 2007 , 45 : 1928 —1933
[26 ]  Kim H , Im D , Doo S G. J . Power Sources , 2007 , 174 : 588 —591
[27 ]  Liu Y, Hanai K, Horikawa K, et al . Mater. Chem. Phys. , 2005 ,89 : 80 —84
[28 ]  Lee H Y, Kim YL , Hong M K, et al . J . Power Sources , 2005 ,141 : 159 —162
[29 ]  Lee H Y, Lee S M. Electrochem. Commun. , 2004 , 6 : 465 —469
[30 ]  Wang Z, Tian W H , Liu X H , et al . Mater. Chem. Phys. , 2006 ,100 : 92 —97
[31 ]  Park MS , Rajendran S , Kang YM, et al . J . Power Sources , 2006 ,158 : 650 —653
[32 ]  Park M S , Lee Y J , Han Y S , et al . Mater. Lett . , 2006 , 60 :3079 —3083
[33 ]  Kasavajjula U , Wang C , Appleby A J . J . Power Sources , 2007 ,163 : 1003 —1039
[34 ]  Guo Z P , Jia D Z, Yuan L , et al . J . Power Sources , 2006 , 159 :332 —335
[35 ]  Zuo P J , Yin G P , Ma Y L. Electrochim. Acta , 2007 , 52 : 4878 —4883
[36 ]  Chen L B , Xie X H , Wang B F , et al . Mat . Sci . Eng. B , 2006 ,131 : 186 —190
[37 ]  Lee J H , Kim WJ , KimJ Y, et al . J . Power Sources , 2008 , 176 :353 —358
[38 ]  Wang K, He X M, Wang L , et al . Solid State Ionics , 2007 , 178 :115 —118
[39 ]  Kwon Y, Park G S , Cho J . Electrochim. Acta , 2007 , 52 : 4663 —4668
[40 ]  Ng S H , Wang J , Konstantinov K, et al . J . Power Sources , 2007 ,174 : 823 —827
[41 ]  Ng S H , Wang J , Wexler D , et al . Angew. Chem. Int . Ed. ,2006 , 45 : 6896 —6899
[42 ]  Dimov N , Kugino S , Yoshio M. Electrochim. Acta , 2003 , 48 :1579 —1587
[43 ]  Buqa H , Grogger C , Besenhard J O , et al . J . Power Sources , 2001 ,97/98 : 126 —128
[44 ]  Jung Y S , Lee K T, Oh S M. Electrochim. Acta , 2007 , 52 :7061 —7067
[45 ]  Obrovac MN , Christensen L. Electrochem. Solid-State Lett . , 2004 ,7 : A93 —A96
[46 ]  Ryu J H , Kim J W, Sung Y E , et al . Electrochem. Solid-State Lett . , 2004 , 7 : A306 —A309
[47 ]  Li J , Dahn J R. J . Electrochem. Soc. , 2007 , 154 : A156 —A161
[48 ]  Yang XL , Wen Z Y, Zhang L L , et al . J . Alloy. Compd. , 2008 ,464 : 265 —269
[49 ]  Yang X L , Wen Z Y, Xu X X, et al . J . Power Sources , 2007 ,164 : 880 —884
[50 ]  Yang J , Takeda Y, Imanishi N , et al . Solid State Ionics , 2002 ,152P153 : 125 —129
[51 ]  Kim I S , Blomgren G E , Kumta P N. J . Power Sources , 2004 , 130 :275 —280
[52 ]  Datta M K, Kumta P N. J . Power Sources , 2006 , 158 : 557 —563
[53 ]  Wang C S , Wu G T, Li W Z. J . Power Sources , 1998 , 76 : 1 —10
[54 ]  Datta M K, Kumta P N. J . Power Sources , 2007 , 165 : 368 —378第10 期陈敬波等 锂离子电池硅基复合物负极材料·2121 ·
[55 ]  Zheng Y, Yang J , Wang J L , et al . Electrochim. Acta , 2007 , 52 :5863 —5867
[56 ]  Chew S Y, Guo Z P , Wang J Z, et al . Electrochem. Commun. ,2007 , 9 : 941 —946
[57 ]  Yu M F , Files B S , Arepalli S , et al . Phys. Rev. Lett . , 2000 , 84 :5552 —5555
[58 ]  Thess A , Lee R , Nikolaev P , Dai H , et al . Science , 1996 , 273 :483 —487
[59 ]  Demczyk B G, Wang YM, Cumings J , et al . Mater. Sci . Eng. A ,2002 , 334 : 173 —178
[60 ]  Wang W, Kumta P N. J . Power Sources , 2007 , 172 : 650 —658
[61 ]  Kim I S , Kumta P N. J . Power Sources , 2004 , 136 : 145 —149
[62 ]  Kim I S , Blomgren G E , Kumta P N. J . Power Sources , 2004 , 130 :275 —280
[63 ]  Salver-Disma F , Lenain C , Beaudoin B , et al . Solid State Ionics ,1997 , 98 : 145 —158
[64 ]  Shu J , Li H , Yang R , et al . Electrochem. Commun. , 2006 , 8 :51 —54
[65 ]  Zhang Y, Zhang X G, Cheng H M, et al . Electrochim. Acta , 2006 ,51 : 4994 —5000
[66 ]  Lee K T, Jung Y S , Oh S M. J . Am. Chem. Soc. , 2003 , 125 :5652 —5653
[67 ]  Kim H , Cho J . Chem. Mater. , 2008 , 20 : 1679 —1681
[68 ]  Zhang W M, Hu J S , Guo Y G, et al . Adv. Mater. , 2008 , 20 :1160 —1165
[1] Yang Chen, Xiaoli Cui. Titanium Dioxide Anode Materials for Lithium-Ion Batteries [J]. Progress in Chemistry, 2021, 33(8): 1249-1269.
[2] Deying Mu, Zhu Liu, Shan Jin, Yuanlong Liu, Shuang Tian, Changsong Dai. The Recovery and Recycling of Cathode Materials and Electrolyte from Spent Lithium Ion Batteries in Full Process [J]. Progress in Chemistry, 2020, 32(7): 950-965.
[3] Zhan Wu, Xiaohan Li, Aowei Qian, Jiayu Yang, Wenkui Zhang, Jun Zhang. Electrochromic Energy-Storage Devices Based on Inorganic Materials [J]. Progress in Chemistry, 2020, 32(6): 792-802.
[4] Zhaoxiang Wang, Jun Ma, Yurui Gao, Shuai Liu, Xin Feng, Liquan Chen. Stabilizing Structure and Performances of Lithium Rich Layer-Structured Oxide Cathode Materials [J]. Progress in Chemistry, 2019, 31(11): 1591-1614.
[5] Yijia Shao, Bin Huang, Quanbing Liu, Shijun Liao. Preparation and Modification of Ni-Co-Mn Ternary Cathode Materials [J]. Progress in Chemistry, 2018, 30(4): 410-419.
[6] Meng Haowen, Ma Daqian, Yu Xiaohui, Yang Hongyan, Sun Yanli, Xu Xinhua. Tin-Metal-Carbon Composite Anode Materials for Lithium Ion Batteries [J]. Progress in Chemistry, 2015, 27(8): 1110-1122.
[7] Liu Xin, Zhao Hailei, Xie Jingying, Lv Pengpeng, Wang Ke, Cui Jiajia. SiOx(0<x≤2) Based Anode Materials for Lithium-Ion Batteries [J]. Progress in Chemistry, 2015, 27(4): 336-348.
[8] Lou Shuaifeng, Cheng Xinqun, Ma Yulin, Du Chunyu, Gao Yunzhi, Yin Geping. Nb-Based Oxides as Anode Materials for Lithium Ion Batteries [J]. Progress in Chemistry, 2015, 27(2/3): 297-309.
[9] Huang Zhao, Wang Dan, Zhang Chunming, He Dannong. Effects of Different Doping Sites on the Structure and Performance of Li4Ti5O12 Material [J]. Progress in Chemistry, 2014, 26(12): 1914-1923.
[10] Liu Xin, Zhao Hailei, Xie Jingying, Wang Ke, Lv Pengpeng, Gao Chunhui. SnS2 Based Anode Materials for Lithium-Ion Batteries [J]. Progress in Chemistry, 2014, 26(09): 1586-1595.
[11] Wang Haiyan*, Tang Yougen, Zhou Donghui, Liu Suqin, Zhang Hui. MV3O8(M=Li+, Na+, NH4+) as Novel Intercalated Materials for Li-Ion Batteries [J]. Progress in Chemistry, 2013, 25(06): 927-939.
[12] Han Fei, Lu Anhui, Li Wencui* . Structure Controlled Carbon-Based Materials for Lithium Ion Battery [J]. Progress in Chemistry, 2012, 24(12): 2443-2456.
[13] Chu Daobao, Li Jian, Yuan Ximei, Li Zilong, Wei Xu, Wan Yong. Tin-Based Alloy Anode Materials for Lithium Ion Batteries [J]. Progress in Chemistry, 2012, 24(08): 1466-1476.
[14] Gao Pengfei, Yang Jun. Si-Based Composite Anode Materials for Li-Ion Batteries [J]. Progress in Chemistry, 2011, 23(0203): 264-274.
[15] Yang Li, Chen Jizhang, Tang Yufeng, Fang Shaohua. Li4Ti5O12 Anode Materials Applied in Lithium Ion Batteries [J]. Progress in Chemistry, 2011, 23(0203): 310-317.