English
往期目录
新闻公告
More
化学进展 2005, Vol. 17 Issue (03): 406-411 前一篇   后一篇

• 综述与评论 •

层状嵌锂多元过渡金属氧化物的研究

黄友元1,2;周恒辉1*;陈继涛1;苏光耀2;高德淑2   

  1. 1.北京大学化学与分子工程学院 北京 100871;

    2.湘潭大学化学学院 湘潭 411105

  • 收稿日期:2004-03-01 修回日期:2004-07-01 出版日期:2005-05-24 发布日期:2005-05-24
  • 通讯作者: 周恒辉
下载PDF ( 2737 ) 引用
导出 被引次数 ( 78 | 5 )

Study of Layered Lithium Intercalation Multi-Element Transition Metal Oxides

Huang Youyuan1,2;Zhou Henghui1*;Chen Jitao1;Su Guangyao2;Gao Deshu2   

  1. 1.College of Chemistry and Molecular Engineering, Peking University,Beijing 100871,China;

    2.College of Chemistry , Xiangtan University,Xiangtan 411105,China;

  • Received:2004-03-01 Revised:2004-07-01 Online:2005-05-24 Published:2005-05-24
  • Contact: Zhou Henghui
综述了近几年来锂离子电池正极材料层状多元过渡金属氧化物的研究进展,重点讨论了具有协同作用的Ni、Co、Mn三元复合型层状正极材料LiCoxMnyNi1-x-yO2 (0<x<0.5,0<y<0.5)及部分二元过渡金属氧化物正极材料锂镍锰氧化物和锂钴锰氧化物的制备方法,以及多元素过渡金属氧化物体系的电化学反应机理及其元素配比变化对材料综合电性能的影响.进一步分析了今后几年这类层状多元过渡金属正极材料研究的可能热点及该类材料走向规模化应用的关键因素.
关键词: 层状结构, 协同作用, 多元过渡金属氧化物, 正极材料, 锂离子电池
The progress of multi-element transition metal oxides as cathode materials for lithium ion batteries is reviewed. The synthesis methods and electrochemical reaction mechanism associated with three-element (Ni^ Co^ Mn) synergetic effect of LiNi,. I_3.Coa:Mn:),O2(0 < x<0.5,0<y<0.5) are discussed in detail, and other duality transition metal oxides including LiNi^,Mn, O2 and LiCo^M^_ xO2 are discussed. The application prospect as cathode materials for lithium ion batteries and further research orientation of these lithium intercalation multi-element transition metal oxides are pointed out.
Key words: layered structure, synergetic effect, multi-element transition metal oxides, cathode materials, lithium ion batteries

中图分类号: 

()

[ 1 ] Carl J R , Bo S. Science of the Total Environment , 2003 , 302 :167 —184
[ 2 ] Jiang J , Dahn J R. Electrochem. Commun. , 2004 , 6 : 39 —43
[ 3 ] Macneil D D , Dahn J R. J . Electrochem. Soc. , 2003 , 150 (1) :A21 —A28
[ 4 ] Julien C M, Massot M. Materials Science and Engineering , 2003 ,B97 : 217 —230
[ 5 ] Tateishi K, Boulay D , Ishizawa N , et al . J . Solid State Chem. ,2003 , 174 : 175 —181
[ 6 ] Paulsen J M, Kieu L Y, Ammundsen B G. EP 1 189 296A2 ,2002
[ 7 ] Amatuccia G, Tarasconb J M. J . Electrochem. Soc. , 2002 , 149(12) : K31 —K46
[ 8 ] Armstrong A R , Bruce P G. Electrochem. Solid State , 2004 , 7(1) : A1 —A4
[ 9 ] Armstrong A R , Bruce P G. Nature , 1996 , 381 (6) : 499 —500
[10] Tom A E , Marca M D. J . Power Sources , 2003 , 119P121 : 145 —149
[11] Stoyanova R , Zhechevaa E , Alca′ntarab R , et al . Solid State Ionics , 2003 , 161 : 197 —204
[12] Macneil D D , Lu Z H , Dahn J R. J . Power Sources , 2002 , 108 :8 —14
[13] 周恒辉(Zhou H H) , 谷亦杰(Gu Y J ) , 陈继涛(Chen J T) 等.电池(Battery Bimonthly) , 2002 , 32 (6) : 337 —339
[14] Ritchie A G. J . Power Sources , 2001 , 96 : 1 —4
[15] Masataka W. Materials Science and Engineering , 2001 , 33 :109 —134
[16] Kalyani P , Kalaiselvi N , Renganathan N G, et al . Materials Research Bulletin , 2004 , 39 : 41 —54
[17] Kang S H , Amine K. J . Power Sources , 2003 , 119/121 : 150 —155
[18] Albrecht S , Kümpers J , Kruft M. J . Power Sources , 2003 , 119/121 : 178 —183
[19] Vasanthyi R , Ruth M I , Selladurai S. Inorganic Chem.Commun. , 2003 , 6 (7) : 953 —957
[20] Kim W S , Chung K, Choi Y K, et al . J . Power Sources , 2003 ,115 (1) : 101 —109
[21] Kawakami S , Yamamoto T. US 6 558 847 , 2003
[22] Chiang Y M, Ceder G, Limthongkul P. US 6 599 662 , 2003
[23] Gao Y, Yakovleva M, Wang H H , et al . US 6 620 400 , 2003
[24] Yang K, McGrath K P , Agarwal N , et al . US 6 623 886 , 2003
[25] Macneil D D , Lu Z H , Dahn J R. J . Electrochem. Soc. , 2002 ,149 (10) : A1332 —A1336
[26] Lu Z H , Dahn J R. J . Electrochem. Soc. , 2001 , 148 ( 3) :A237 —A240
[27] Jouanneau S , Dahn J R. Chem. Materials , 2003 , 15 (2) : 495 —499
[28] Jouanneau S , Macneil D D , Dahn J R , et al . J . Electrochem.Soc. , 2003 , 150 (10) : A1299 —A1304
[29] Jouanneau S , Eberman KW, Dahn J R , et al . J . Electrochem.Soc. , 2003 , 150 (12) : A1637 —A1642
[30] Lu Z H , Macneil D D , Dahn J R. Electrochem. Solid State Lett . , 2001 , 4 (12) : A200 —A203
[31] Paulsen J M, Mueller-Neuhaus J R , Dahn J R. J . Electrochem.Soc. , 2000 , 147 (2) : 508 —516
[32] Park S H , Yoon C S , Kang G, et al . Electrochimica Acta , 2004 ,49 : 557 —563
[33] Lu Z H , Macneil D D , Dahn J R . Electrochem. Solid State Letters , 2001 , 4 (11) : A191 —A194
[34] Ohzuku T, Makimura Y. Chem. Lett . , 2001 (7) : 642 —643
[35] 谷亦杰( Gu Y J ) , 北京大学博士后出站报告( Post PhD Dissertation of Peking Univ. ) , 2003
[36] Koyama Y, Tanaka I , Ohzuku T, et al . J . Power Sources , 2003 ,119/121 : 644 —648
[37] Hwang B J , Tsai Y W, Chen C H. J . Mater. Chem. , 2003 , 13 :1962 —1968
[38] Masaki Y, Hideyuki N , Okada T M. J . Power Sources , 2000 ,90 : 176 —181
[39] Liu Z L , Yu A S , Lee J Y. J . Power Sources , 1999 , 81/82 :416 —419
[40] KimJ H , Park C W, Sun Y K. Solid State Ionics , 2003 , 164 :43 —49
[41] Chen Y, Wang G X, Konstantinov K, et al . J . Power Sources ,2003 , 119/121 : 184 —188
[42] Naoaki Y, Ohuzuku T. J . Power Sources , 2003 , 119/121 : 171 —174
[43] Wan G X, Bewlay S , Yao J , et al . J . Power Sources , 2003 ,119/121 : 189 —194
[44] Paulsen J M, Kieu L Y, Ammundsen B G, et al . EP1 189 296A2
[45] Ngala J K, Chernova N A , Whittingham M S , et al . J . Mater.Chem. , 2004 , 14 (2) : 214 —220
[46] Barker J , Saidi M Y, Swoyer J L. Electrochem. Solid State Lett . 2003 , 6 (3) : 53 —55
[47] Yang S F , Song Y N , Ngala K, et al . J . Power Sources , 2003 ,119/121 : 239 —246
[48] Yin S C , Grondey H , Nazar L F , et al . J . Am. Chem. Soc. ,2003 , 125 : 326 —327
[49] Thackeray M. Nature Mater. , 2002 , 1 : 81 —82
[50] Tarascon J M, Armand M. Nature , 2001 , 414 : 359 —367
[51] Nanjundaswamy K S , Padhi A K, Goodenough J B , et al . Solid State Ionics , 1996 , 92 : 1 —10
[52] 周恒辉(Zhou H H) , 陈继涛(Chen J T) , 徐小明(Xu X M) .CN 1 401 559A , 2003
[53] Chen Z H , Dahn J R. Electrochem Solid State , 2003 , 6 (11) :A221 —A224
[54] Masaru H , Fuminobu T, Yuki T, et al . US 6 261 712B1 , 2001
[55] Satch K, Nohma T, Nakanishi N , et al . EP 1 193 782A2 , 2002
[56] Steven T M, San L. US 6 379 842B1 , 2002
[57] Matsumoto K, Tujimura T, Takeishi K, et al . US 6 617 073B1 ,2003
[58] Broussely M, Blanchard P , Biensan P , et al . J . Power Sources ,2003 , 119/121 : 859 —864
[59] Chen Z H , Dahn J R. Electrochem. Solid State , 2004 , 7 (1) :A11 —A14
[60] Gao Y, Yakovleva M, Wang H H. US 6 589 499 , 2003
[61] Kosova N V , Kaichev V V. Bukhtiyarov V I. J . Power Sources ,2003 , 119/121 : 669 —673
[62] Kim KW, Woo S I , Choi K H. Solid State Ionics , 2003 , 159 :25 —34
[63] 桂阳海( Gui Y H) , 胡国荣( Hu G R) . 电池( Battery Bimonthly) , 2003 , 33 (1) : 51 —54
[63] 张爱波( Zhang A B) , 刘建睿(Liu J R) , 黄卫东(Huang W D) . 电源技术(Chinese Journal of Power Sources) , 2003 , 27(5) : 484 —490
[65] 钟辉(Zhong H) , 周艳芳(Zhou Y F) , 许惠(Xu H) . 化学通报(Chemistry) , 2003 , 7 : 449 —453
[66] Zhang L Q , Noguchi H , Yoshio M. J . Power Sources , 2002 ,110 : 57 —64
[67] Wu Q , Li X L , Jiang Z Y, et al . Electrochem. Commun. , 2003 ,5 : 878 —882
[68] Paulsen J M, Dahn J R. J . Electrochem. Soc. , 2000 , 147 (7) :2478 —2485
[69] Sun Y K, Yoon C S , Lee Y S. Electrochimica Acta , 2003 , 48 :2589 —2592
[70] Park S H , Kang S K, Sun Y K, et al . Chem. Lett . , 2003 , 32(5) : 446 —447
[71] Makimura Y, Ohzuku T. J . Power Sources , 2003 , 119/121 :156 —160
[72] Park S H , Sung WO , Sun Y K, et al . Chem. Lett . , 2004 , 33(1) : 2 —3
[73] Fey G T K, Lu C Z, Kumar T P. J . Power Sources , 2003 , 115 :332 —345
[74] Lu Z H , Macneil D D , Dahn J R. Electrochem. Solid State Lett . , 2001 , 4 (11) : A191 —A194
[75] Kang S H , Kim J , Amine K, et al . J . Power Sources , 2002 ,112 : 41 —48
[76] Albrecht S , Kumpers J , Kruft M, et al . J . Power Sources , 2003 ,119/121 : 178 —183
[77] Cushing B L , Goodenough J B. Solid State Sci . , 2002 , 4 (11/12) : 1487 —1493
[78] Hironori K, Yoshinori A , Hiroyuki K. J . Mater. Chem. , 2004 ,14 (1) : 40 —42
[79] Ohzuku T, Makimura Y. Chem. Lett . , 2001 , 8 : 744 —745
[80] Shaju K M, Subba R G V , Chowdari B V R. Electrochimica Acta , 2003 , 48 : 1505 —1514
[81] Lu Z H , Chen Z H , Dahn J R. Chem. Mater. , 2003 , 15 (16) :3214 —3220
[82] Ito Y, Idemoto Y, Tsunoda Y. J . Power Sources , 2003 , 119/121 : 733 —737
[83] KimJ H , Sun Y K. J . Power Sources , 2003 , 119/121 : 166 —170
[84] Gopukumar S , Chung K Y, Kim K B. Electrochimica Acta ,2004 , 49 (5) : 803 —810
[85] Armstrong A R , Robertso A D , Bruce P G. Electrochimica Acta ,1999 , 45 : 285 —294
[86] Armstrong A R , Robertso A D , Bruce P G, et al . J . Solid State Chem. , 1999 , 145 : 549 —556
[87] Landa A I , Chang C C , Kumta P N , et al . Solid State Ionics ,2002 , 149 : 209 —215
[88] Akihisa K, Kazunori T, Taro I , et al . Solid State Ionics , 2002 ,149 : 39 —45
[89] Seung-Taek M, Shinichi K, Naoaki K. J . Electrochem. Soc. ,2002 , 149 (10) : A1349 —A1357
[90] Akihisa K, Kazunori T, Taro I , et al . Solid State Ionics , 2002 ,149 : 39 —45
[91] Akihisa K, Kazunori T, Taro I , et al . J . Electrochem. Soc. ,2001 , 148 (9) : A981 —A983
[92] Ikuo Y, Takugo O , Mamoru W, et al . Solid State Ionics , 2002 ,151 : 189 —196
[93] Shaju K M, Subba Rao G V , Chowdari B V R , Solid State Ionics ,2002 , 152/153 : 69 —81
[94] Shaju K M, Subba Rao G V , Chowdari B V R. Electrochimica Acta , 2003 , 48 : 2691 —2703
[95] Franger S , Bach S , Farcy J , et al . Electrochimica Acta , 2003 ,48 : 891 —900
[1] 朱国辉, 还红先, 于大伟, 郭学益, 田庆华. 废旧锂离子电池选择性提锂[J]. 化学进展, 2023, 35(2): 287-301.
[2] 李芳远, 李俊豪, 吴钰洁, 石凯祥, 刘全兵, 彭翃杰. “蛋黄蛋壳”结构纳米电极材料设计及在锂/钠离子/锂硫电池中的应用[J]. 化学进展, 2022, 34(6): 1369-1383.
[3] 李婧婧, 李洪基, 黄强, 陈哲. 掺杂对钠离子电池正极材料性能影响机制的研究[J]. 化学进展, 2022, 34(4): 857-869.
[4] 冯小琼, 马云龙, 宁红, 张世英, 安长胜, 李劲风. 铝离子电池中过渡金属硫族化合物正极材料[J]. 化学进展, 2022, 34(2): 319-327.
[5] 王才威, 杨东杰, 邱学青, 张文礼. 木质素多孔碳材料在电化学储能中的应用[J]. 化学进展, 2022, 34(2): 285-300.
[6] 蔡克迪, 严爽, 徐天野, 郎笑石, 王振华. 锂离子电容电池关键电极材料[J]. 化学进展, 2021, 33(8): 1404-1413.
[7] 陈阳, 崔晓莉. 锂离子电池二氧化钛负极材料[J]. 化学进展, 2021, 33(8): 1249-1269.
[8] 陆嘉晟, 陈嘉苗, 何天贤, 赵经纬, 刘军, 霍延平. 锂电池用无机固态电解质[J]. 化学进展, 2021, 33(8): 1344-1361.
[9] 高金伙, 阮佳锋, 庞越鹏, 孙皓, 杨俊和, 郑时有. 高电压锂离子正极材料LiNi0.5Mn1.5O4高温特性[J]. 化学进展, 2021, 33(8): 1390-1403.
[10] 黄国勇, 董曦, 杜建委, 孙晓华, 李勃天, 叶海木. 锂离子电池高压电解液[J]. 化学进展, 2021, 33(5): 855-867.
[11] 周世昊, 吴贤文, 向延鸿, 朱岭, 刘志雄, 赵才贤. 水系锌离子电池锰基正极材料[J]. 化学进展, 2021, 33(4): 649-669.
[12] 张长欢, 李念武, 张秀芹. 柔性锂离子电池的电极[J]. 化学进展, 2021, 33(4): 633-648.
[13] 穆德颖, 刘铸, 金珊, 刘元龙, 田爽, 戴长松. 废旧锂离子电池正极材料及电解液的全过程回收及再利用[J]. 化学进展, 2020, 32(7): 950-965.
[14] 庄全超, 杨梓, 张蕾, 崔艳华. 锂离子电池的电化学阻抗谱分析研究进展[J]. 化学进展, 2020, 32(6): 761-791.
[15] 吴战, 李笑涵, 钱奥炜, 杨家喻, 张文魁, 张俊. 基于无机电致变色材料的变色储能器件[J]. 化学进展, 2020, 32(6): 792-802.