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化学进展 2009, Vol. 21 Issue (09): 1772-1781 前一篇   后一篇

• 综述与评论 •

离子液体的QSPR/QSAR研究

郑燕升*|莫倩|刘昭明   

  1. (广西工学院生物与化学工程系    |柳州   |545006)
  • 收稿日期:2008-10-15 修回日期:2008-11-26 出版日期:2009-09-24 发布日期:2009-09-15
  • 通讯作者: 郑燕升 E-mail:zhyansh88@163.com
  • 基金资助:

    省级资助

下载PDF ( 2286 ) 引用
导出 被引次数 ( 26 | 4 )

The Studies of QSPR/QSAR for Ionic Liquids

Zheng Yansheng*; |Mo Qian ; |Liu Zhaoming   

  1. (Department of Biological and Chemical Engineering, Guangxi University of Technology, Liuzhou, 545006, China)
  • Received:2008-10-15 Revised:2008-11-26 Online:2009-09-24 Published:2009-09-15
  • Contact: Zheng Yansheng E-mail:zhyansh88@163.com

离子液体以其独特的性质广受关注,人们对其潜在的应用价值做了大量的研究,但对离子液体特性和结构与性质/活性相关的研究却很少。本文综述了离子液体定量结构-性质/活性相关(QSPR/QSAR)研究的最新进展,重点介绍了QSPR/QSAR的基本原理和离子液体的熔点、有机化合物在离子液体中的无限稀释活度系数、离子液体的界面张力、有机物在离子液体中的溶解系数和分配系数、离子液体的电导率和黏度以及离子液体的毒性等性质与分子结构的定量关系,并对离子液体分子结构与性质/活性的定量相关研究的发展趋势进行了展望。

关键词: 离子液体, 定量结构-性质相关(QSPR), 定量结构-活性相关(QSAR)

Ionic liquids (ILs) have attracted large amount of interest due to their unique properties. Although a lot of efforts have been focused on the investigation of their potential applications, characterization of ionic liquids and structure-property/activity relationships of ionic liquids are poorly understood. The recent progress in quantitative structure-property/activity relationship (QSPR/QSAR) studies of ionic liquids is reviewed.The principle of QSPR/QSAR, quantitative structure-property/activity relationship studies on the melting points of ionic liquids, infinite dilution activity coefficients of organic compounds, surface tensions of ionic liquids, solubility and partition coefficients of organic solutes in ionic liquids , conductivities and viscosities of ionic liquids and the toxicity of ionic liquids are introduced. The trend of QSPR/QSAR studies on ionic liquids is discussed.

Contents
1 Introduction
2 The research methods of QSPR/QSAR
3 QSPR/QSAR for ionic liquids
3.1 Exploration of QSPR/QSAR for the melting points(Tm) of ionic liquids
3.2 Exploration of QSPR/QSAR for the infinite dilution activity coefficients (γi)of organic compounds in ionic liquids
3.3 Exploration of QSPR/QSAR for the surface tensions (σ) of ionic liquids
3.4 Exploration of QSPR/QSAR for the conductivities (κ)and viscosities(η) of ionic liquids
3.5 Exploration of QSPR/QSAR for the Ostwald solubility and partition coefficients of organic solutes in ionic liquids
3.6 Exploration of QSPR/QSAR for the toxicity of ionic liquids
4 Conclusion and perspective

Key words: ionic liquids(ILs), quantitative structure-property relationships (QSPR), quantitative structure-activity relationships (QSAR)

中图分类号: 

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[ 1 ]  Huddleston J G, Visser A E , Reichert WM. Green Chem. , 2001 ,3 : 156 —164
[ 2 ]  Welton T. Chem. Rev. , 1999 , 99 (8) : 2071 —2083
[ 3 ]  Davis J H. Chem. Lett . , 2004 , 33 (9) : 1072 —1077
[ 4 ]  Chiappe C , Pieraccini D. J . Phys. Org. Chem. , 2005 , 18 (4) :275 —297
[ 5 ]  Handy S T. Curr. Org. Chem. , 2005 , 9 (10) : 959 —988
[ 6 ]  刘伟山(Liu W S) , 陶国宏(Tao G H) , 何玲(He L) . 有机化学(Chinese Journal of Organic Chemistry) , 2006 , 26 (8) : 1031 —1038
[ 7 ]  王均凤(Wang J F) , 张锁江(Zhang S J ) , 陈慧萍(Chen H P) .过程工程学报(Chinese Journal of Process Engineering) , 2003 , 3(2) : 177 —185
[ 8 ]  Wiener H. J . Am. Chem. Soc. , 1947 , 69 (1) : 17 —21
[ 9 ]  Murugan R , Grendze M P , Toomey J E , et al . Chemtech , 1994 ,24 : 17 —23
[10 ]  Karelson M, Maran U , Wang Y, et al . Collect . Czech. Chem.Commun. , 1999 , 64 : 1551 —1574
[11 ]  Katritzky A R , Petrukhin R , Tatham D , et al . J . Chem. Inf .Comput . Sci . , 2001 , 41 : 679 —685
[12 ]  Katritzky A R , Fara D C , Petrukhin R O , et al . Curr. Top. Med.Chem. , 2002 , 2 : 1333 —1356
[13 ]  Blum D J W, Speece R E. Environ. Sci . Technol . , 1990 , 24 :284 —293
[14 ]  Kamlet MJ , Doherty R M, Abraham M H , et al . J . Phys. Chem. ,1988 , 92 (18) : 5244 —5255
[15 ]  Katritzky A R , Lomaka A , Petrukhin R , et al . J . Chem. Inf .Comput . Sci . , 2002 , 42 : 71 —74
[16 ]  Katritzky A R , Jain R , Lomaka A , et al . J . Chem. Inf . Comput .Sci . , 2002 , 42 : 225 —231
[17 ]  Eike D M, Brennecke J F , Maginn E J . Green Chem. , 2003 , 5 :323 —328
[18 ]  Sun N , He X Z, Dong K, et al . Fluid Phase Equilib. , 2006 , 246 :137 —142
[19 ]  Trohalaki S , Pachter R , Drake G W, et al . Energy Fuels , 2005 ,19 : 279 —284
[20 ]  Carrera V S M, Branco C , Afonso A M, et al . Tetrahedron , 2008 ,64 : 2216 —2224
[21 ]  沈树宝(Shen S B) , 汪绍 (Wang S K) , 张菊珍(Zhang J Z) .化工学报(Journal of Chemical Industry and Engineering) , 1988 ,4 : 501 —507
[22 ]  Diedenhofen M, Eckert F , Klamt A. J . Chem. Eng. Data , 2003 ,48 (3) : 475 —479
[23 ]  Eike D M, Brennecke J F , Maginn E. J . Ind. Eng. Chem. Res. ,2004 , 43 (4) : 1039 —1048
[24 ]  朱吉钦(Zhu J Q) , 于燕梅(Yu YM) , 陈健(Chen J ) . 化工学报(Journal of Chemical Industry and Engineering) , 2006 , 57 ( 8) :1835 —1840
[25 ]  T?mm K, Burk P. J . Mol . Model , 2006 , 12 : 417 —421
[26 ]  Huddleston J G, Visser A E , Reichert W M, et al . Green Chem. ,2001 , 3 (4) : 156 —164
[27 ]  Gardas R L , Coutinho J A P. Fluid Phase Equilib. , 2008 , 265 :57 —65
[28 ]  Bonhǒte P , Dias A P , Papagerogiou N , et al . Inorg. Chem. , 1996 ,35 (5) : 1168 —1178
[29 ]  Matsuda H , Yamamoto H , Kurihara K, et al . Fluid Phase Equilib. ,2007 , 261 : 434 —443
[30 ]  Katritzky A R , Kuanar M, Slavov S H. J . Chem. Eng. Data , 2008 ,53 (5) : 1085 —1092
[31 ]  Jastorff B , Stêrmann R , Ranke J . Green Chem. , 2003 , 5 : l36 —142
[32 ]  Gathergood N , Garcia M T, Scammells P J . Green Chem. , 2004 ,6 : l66 —175
[33 ]  Garcia M T, Gathergood N , Scammells P J . Green Chem. , 2005 ,7 : 9 —l4
[34 ]  Bernot R J , Brueseke M A , Evans-White M A , et al . Environ.Toxico1. Chem. , 2005 , 24 : 87 —92
[35 ]  Bernot R J , Kennedy E , Lamberti GA. Environ. Toxico1. Chem. ,2005 , 24 : 1759 —1765
[36 ]  Gathergood N , Scammells P J , Garcia M T. Green Chem. , 2006 ,8 : 156 —160
[37 ]  Pretti C , Chiappe C , Pieraccini D , et al . Green Chem. , 2006 , 8 :238 —240
[38 ]  Couling D J , Bernot R J , Docherty K M, et al . Green Chem. ,2006 , 8 : 82 —90
[39 ]  Luis P , Ortiz I , Aldaco R , et al . Ecotoxicol . Environ. Saf . , 2007 ,67 : 423—429
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离子液体的QSPR/QSAR研究