English
往期目录
新闻公告
More
化学进展 2006, Vol. 18 Issue (12): 1677-1683 前一篇   后一篇

• 综述与评论 •

多功能性聚吡咯复合膜

谢允斌 黄美荣 李新贵   

  1. 同济大学材料学院
  • 收稿日期:2006-05-05 修回日期:2006-05-19 出版日期:2006-12-24 发布日期:2006-12-25
  • 通讯作者: 李新贵
下载PDF ( 2645 ) 引用
导出 被引次数 ( 31 | 6 )

Multifunctional Polypyrrole Composite Films

Yunbin Xie Meirong Huang Xingui Li   

  • Received:2006-05-05 Revised:2006-05-19 Online:2006-12-24 Published:2006-12-25
  • Contact: Xingui Li
聚吡咯具有较高的电导率与良好的环境稳定性,被视为继聚苯胺之后最有工业化应用前景的导电高分子材料之一。聚吡咯与常规聚合物基体如聚乙烯醇、聚氯乙烯等形成的复合膜不仅可以综合聚吡咯奇异的多功能性与常规聚合物的易成膜性和低成本性于一体,而且可望发挥两者的协同效应,从而大大拓宽其应用领域。该研究已经成为导电聚合物研究领域中的又一新热点。作者系统论述了制备这类功能复合膜的两种典型制备方法,并在分析各自特点的基础上提出了改进与发展方向,指出聚吡咯复合膜具有广泛可调的电导率、快速的电学响应性以及稳定的电致变色性等多种功能,在透明导电膜、化学传感器、生物分离膜、电致变色膜领域具有诱人的应用前景。
关键词: 聚吡咯, 多功能性, 复合膜
Polypyrrole has been considered one of the most prospective conducting polymers for industrial applications following polyaniline for its high conductivity and good environmental stability. Composite films from polypyrrole and some conventional polymer matrixes such as poly(vinyl alcohol), poly(vinyl chloride), could not only integrate the exicting multifunctionality of polypyrrole as well as the good film-formability and much lower cost of the matrix polymers, but also produce a novel coadjutant effect of both polymers. Therefore these kinds of composite films have widened application fields, and have become a new research hotspot in the fields of conducting polymers. Two typical preparation methods of these conductive polypyrrole composite films have been systematically reviewed. According to careful analysis of their individual characteristics,the possible improvement and development are proposed. Having a variety of excellent functions such as widely-variable electroconductivity, fast electrical response and stable electrochromism, the polypyrrole composite films have shown a great attractionof potential applications in many fields including transparent conducting films, chemical sensors, bioseparation, and electrochromic films.
Key words: polypyrrole, multifunctionality, composite films

中图分类号: 

()

[ 1 ] Gangopadhyay R , De A. Chem. Mater. , 2000 , 12 (3) : 608 —622
[ 2 ] Ramanaviciene A , Ramanavicius A. Crit . Rev. Anal . Chem. ,2002 , 32(3) : 245 —252
[ 3 ] Onoda M, Tada K. IEICE Transact . Electronics , 2004 , E87-C (2) : 128 —135
[ 4 ] Ameer Q , Adeloju S B. Sens. Actuators B , 2005 , 106 ( 2) :541 —552
[ 5 ] Samir F , Benseddik E , Corraze B , et al . Synth. Met . , 1995 ,69 : 341 —342
[ 6 ] Mano V , Felisberti M I , Matencio T , et al . Polymer , 1996 , 37 :5165 —5170
[ 7 ] Chakraborty M, Mukherjee D C , Mandal B M. Synth. Met . ,1999 , 98 : 193 —200
[ 8 ] 宋志刚(Song Z G) , 李长江(Li C J ) . 北京化工学院学报(Journal of Beijing Institute of Chemical Technology) , 1991 , 18 :80 —85
[ 9 ] 王长松(Wang C S) , 黎前跃(Li Q Y) , 周本濂(Zhou B L) ,等. 功能高分子学报(Journal of Functional Polymer) , 1998 ,11 : 167 —171
[10] Migahed M D , Fahmy T , Ishra M, et al . Polym. Test . , 2004 ,23 : 361 —365
[11] Yin W S , Liu H W, Yin B N , et al . Eur. Polym. J . , 1998 , 34 :779 —782
[12] Yin W S , Yan T J , Gan L M, et al . Eur. Polym. J . , 1998 , 34 :1763 —1766
[13] Yin W S , Liu H W, Li J , et al . J . Appl . Polym. Sci . , 1997 ,64 : 2293 —2298
[14] Yin W S , Li J , Li Y M, et al . J . Appl . Polym. Sci . , 2001 ,80 : 1368 —1373
[15] Wang H L , Fernandez J E. Macromolecules , 1993 , 26 : 3336 —3339
[16] Pruneanu S , Resel R , Leising G, et al . Mater. Chem. Phys. ,1997 , 48 : 240 —245
[17] Wang H L , Toppare L , Fernandez J E. Macromolecules , 1990 ,23 : 1053 —1059
[18] Shibata M, Kawashita K I , Yosomiya R , et al . Eur. Polym. J . ,2001 , 37 : 915 —919
[19] Wang H L , Fernandez J E. Macromolecules , 1992 , 25 : 6179 —6184
[20] 马文石(Ma W S) , 龚克成(Gong K C) . 高分子材料科学与工程( Polymer Materials Science & Engineering) , 1998 , 14 :110 —113
[21] Chen X B , Issi J P , Devaux J , et al . J . Mater. Sci . , 1997 , 32 :1515 —1518
[22] 陈雨萍(Chen Y P) , de Jesus C , Weiss R A. 高分子学报(Acta Polymerica Sinica) , 1996 , (1) : 72 —76
[23] Ruangchuay L , Sirivat A , Schwank J . React . Funct . Polym. ,2004 , 61 : 11 —22.
[24] Dutta P , De S K. Synth. Met . , 2003 , 139 : 201 —206
[25] Ruangchuay L , Sirivat A , Schwank J . Talanta , 2003 , 60 :25 —30
[26] Zachara J E , Toczylowska R , Pokrop R , et al . Sens. Actuators B , 2004 , 101 : 207 —212
[27] Okuzaki H , Kuwabara T , Kondo T. J . Polym. Sci . Polym.Phys. Ed. , 1998 , 36 : 2635 —2642
[28] Shi G, Rouabhia M, Wang Z , et al . Biomaterials , 2004 , 25 :2477 —2488
[29] De Paoli M A , Waltman R J , Diaz A F , et al . J . Polym. Sci .Polym. Chem. Ed. , 1985 , 23 : 1687 —1698
[30] Chen YP , Qian R Y, Li G, et al . Polym. Commun. , 1991 , 32 :189 —192
[31] Byun S W, Im S S. Synth. Met . , 1993 , 55P57 : 3501 —3506
[32] Bhat N V , Gadre A P , Bambole V A. J . Appl . Polym. Sci . ,2003 , 88 : 22 —29
[33] Gangopadhyay R , De A. Sens. Actuators B , 2001 , 77 : 326 —329
[34] Lin C W, Hwang B J , Lee C R. Mater. Chem. Phys. , 1998 ,55 : 139 —144
[35] Otero T F , Bengoechea M. Electrochimica Acta , 1996 , 41 :1871 —1876
[36] Jang J , Oh J H , Stucky G D. Angew. Chem. Int . Ed. , 2002 ,41 : 4016 —4019
[37] Jiang L S , Jun H K, Hoh Y S , et al . Sens. Actuators B , 2005 ,105 : 132 —137
[38] Harsányi G, RéczeyM, Dobay R , et al . Sens. Rev. , 1999 , 19 :128 —134
[39] Selampinar F , Toppare L , Akbulut U , et al . Synth. Met . , 1995 ,68 : 109 —116
[40] Yang X, Too C O , Ramshaw J , et al . React . Funct . Polym. ,2002 , 53 : 53 —62
[41] Wang Z X, Roberge C , Wan Y, et al . J . Biomed. Mater. Res.Part A , 2003 , 66 : 738 —746
[42] Nikpour M, Chaouk H , Mau A , et al . Synth. Met . , 1999 , 99 :121 —126
[43] Zhou D , Too C O , Wallace G G, et al . React . Funct . Polym. ,2000 , 45 : 217 —226
[44] Somani P , Radhakrishnan S. Chem. Phys. Lett . , 1998 , 292 :218 —222
[45] Somani P , Radhakrishnan S. Mater. Chem. Phys. , 2002 , 77 :117 —133
[46] Li X G, Wang L X, Jin Y, et al . J . Appl . Polym. Sci . , 2001 ,82 : 510 —518
[47] Li X G, Chen R F , Huang M R , et al . J . Polym. Sci . Polym.Chem. , 2004 , 42 : 2073 —2092
[1] 许金凯, 蔡倩倩, 于占江, 廉中旭, 田纪文, 于化东. 金属基仿生超滑表面制造及其应用[J]. 化学进展, 2021, 33(6): 958-974.
[2] 汪润田, 柳春丽, 陈振斌. 印迹复合膜[J]. 化学进展, 2020, 32(7): 989-1002.
[3] 黄晚秋, 高苗苗, 窦红静. 聚吡咯及其纳米复合材料在光热治疗领域的应用[J]. 化学进展, 2020, 32(4): 371-380.
[4] 邓璐遥, 李少路, 秦一文, 胡云霞. 抗污染薄层复合聚酰胺膜的结构设计及改性策略[J]. 化学进展, 2020, 32(12): 1895-1907.
[5] 谭远铭, 孟皓, 张霞. 功能化MOFs及MOFs/聚合物复合膜在有机染料和重金属离子吸附分离中的应用[J]. 化学进展, 2019, 31(7): 980-995.
[6] 展侠, 孙晓芳, 徐恒俐, 李继定. 渗透汽化汽油脱硫膜材料[J]. 化学进展, 2019, 31(5): 752-759.
[7] 杨皓程, 陈一夫, 叶辰, 万灵书, 徐志康. 有机-无机复合多孔膜制备与应用[J]. 化学进展, 2015, 27(8): 1014-1024.
[8] 卞书娟, 吴宏庆, 江旭恒, 龙亚峰, 陈勇. 复合介孔二氧化硅膜的制备及应用[J]. 化学进展, 2014, 26(08): 1352-1360.
[9] 李涛 钟贵明 杨勇. 直接甲醇燃料电池用阻醇全氟磺酸复合质子交换膜*[J]. 化学进展, 2010, 22(0203): 522-536.
[10] 洪厚胜 陈龙祥 由涛 张庆文. 渗透汽化复合膜* [J]. 化学进展, 2009, 21(10): 2229-2234.
[11] 吴礼光,周勇,张林,陈欢林,高从堦. 反渗透复合膜功能材料研究进展[J]. 化学进展, 2008, 20(0708): 1216-1221.
[12] 汤蓓蓓,徐铜文,武培怡. 界面聚合法制备复合膜*[J]. 化学进展, 2007, 19(9): 1428-1435.
[13] 张亚萍 徐铜文 . 荷电膜的膜电位研究进展[J]. 化学进展, 2006, 18(12): 1592-1598.
[14] 刘伟,张宝泉,刘秀凤. 钯复合膜的研究进展*[J]. 化学进展, 2006, 18(11): 1468-1481.
[15] 黄彦,李雪,范益群,徐南平. 透氢钯复合膜的原理、制备及表征*[J]. 化学进展, 2006, 18(0203): 230-237.
阅读次数
全文


摘要

多功能性聚吡咯复合膜