烷基烯丙基琥珀酸酯磺酸钠有序聚集体的形成、聚合及应用
|
摘要
表面活性剂有序聚集体在生命、医药、能源、材料等领域已得到了广泛的应用,由于表面活性剂有序聚集体是靠分子间的作用力形成的,所形成的结构容易随着外界条件的变化(如浓度、盐离子强度、温度等)而不稳定。因此,提高表面活性剂有序聚集体的稳定性研究已成为热点课题。如果使用可聚合表面活性剂形成有序聚集体,然后用聚合的方法固定它们的结构,这将有效地提高有序聚集体的稳定性。
设计并合成了结构新型的可聚合表面活性剂——烷基烯丙基琥珀酸双酯磺酸钠系列产物,并对其结构进行了确证,对其表面性能进行了测试,为乳液聚合、微乳液聚合的应用以及聚合囊泡等可聚合有序聚集体的构建提供了新的可聚合表面活性剂品种。
以十四烷基烯丙基琥珀酸酯磺酸钠(STASD)和十六烷基三甲基溴化铵(CTAB)配制可聚合囊泡,对囊泡聚合前后的稳定性及影响因素进行了研究。得出采用过硫酸铵(APS)作引发剂,在80℃下聚合1.5小时的样品经过~1HNMR判断囊泡中双键的转化率为3.14%,该样品在常温下可稳定存放8个月,而一般囊泡只能存放3周左右,经聚合后的囊泡稳定性大大提高。在国内,首次利用可聚合表面活性剂制备的聚合囊泡用于药物载体研究,聚合囊泡对阿司匹林的包封率比未聚合囊泡高15~20%。50小时检测期内,在模拟肠液中,未聚合囊泡中阿司匹林释放率达79%左右,聚合囊泡释放率仅为29%左右;在模拟胃液中,未聚合囊泡中阿司匹林释放率达56%左右,聚合囊泡释放率仅为23%左右。相比于未聚合囊泡,聚合囊泡对阿司匹林有非常明显的缓释效果。这些研究开创了自发形成聚合囊泡和取代非自发制备脂质体作为药物载体的先河。
采用十二烷基烯丙基琥珀酸酯磺酸钠(SDASD)做乳化剂制备微乳液,并用该体系制备多孔聚合物——高吸油性树脂。利用电导率法确定了微乳液的三种亚结构,同时考察了m(MAA)/m(LMA)和SDASD的质量百分含量对微乳液区域大小的影响。详细探讨了微乳液的双连续区域、单体种类及配比、聚合温度、交联剂用量等工艺因素对合成树脂的吸油率和吸油速率的影响,得出最佳聚合工艺条件,在最优工艺条件下制得的树脂吸油效果为7.9g/g(以汽油计)。可聚合表面活性剂的应用减少了微乳聚合过程中相分离的发生,树脂的孔结构易于调控,为高吸油性树脂的制备提供了一种新的思路。
利用SDASD做乳化剂,采用离子液体代替水制备微乳液并用该体系制备透明多孔聚合物,用电导法确定了单相微乳液区存在[bmim] [BF_4] /丙烯酸酯、双连续相、丙烯酸酯/ [bmim][BF_4]三种亚结构。探讨了微乳液亚结构类型、双连续相中水的加入、聚合产物的后处理方法对聚合物的孔结构和透明性的影响。然后在最佳质量配比下进行最佳工艺条件的探究,得出离子液体微乳液聚合制备丙烯酸酯透明多孔聚合物的最佳工艺条件。可聚合表面活性剂和离子液体的引入减少了微乳聚合中相分离的发生和增加了产物的透明性和多孔性。这些研究使微乳液聚合在保持聚合前的理想结构方面取得了进展,丰富了透明多孔聚合物的制备方法。
Ordered self-assemblies of surfactants have been widely and successfully used in the fields of life science, medicine, energy, material science, etc. Unfortunately, the self-assemblies are often formed owing to the interactions of surfactants molecules. The microstructures of aggregates are often changed with environment conditions such as consistence, ion intensity, temperature and so on. Thus, improving the stability of self-assemblies has been a hot topic recently. If polymerizable surfactants are employed to fabricat ordered self-assemblies and these structures are fixed by polymerization, then stability of the ordered self-assemblies will be efficiently improved.
A series of novel polymerizable surfactants - Sodium Alkyl Allyl Sulfosuccinic Diesters were designed and synthesized in this work. The structures of all products were determined by IR and ~1HNMR. The surface properties were also tested. This provied new polymerizable surfactants for emulsion and microemulsion polymerization and polymerizable ordered self-assemblies such as polymerized vesicles.
Polymerized vesicles were prepared spontaneously from aqueous mixtures of polymerizable surfactant - Sodium Tetradecyl Allyl Sulfosuccinic Diester (STASD) and Cetyl Trimethyl Ammonium Bromide (CTAB). The stability of the vesicles against salts, ethanol, temperature, and staying time was studied before and after polymerization. Adopting APS as initiator, double bond of the vesicles which polymerized for 1.5 h at 80℃had translated 3.14% by ~1HNMR. The polymerized vesicles could be preserved for eight months and the unpolymerized vesicles for three weeks at normal temperature. It was found that stability of the vesicles was markedly enhanced after polymerization. We firstly applied the polymerized vesicles formed from polymerizable surfactants as drug carriers. The encapsulation efficiency of the polymerized vesicles for aspirin was 15~20% higher than the unpolymerized vesicles. During 50 h , the release ratio the polymerized vesicles was about 79% , but the unpolymerized vesicles was about 29% in simulated intestinal fluid , and the release ratio the polymerized vesicles was about 56%, but the unpolymerized vesicles was about 23% in simulated gastric fluid .Compared with unpolymerized vesicles, the polymerized vesicles have higher encapsulation efficiency and distinctly slow release effects for encapsulated aspirin. All the results lead spontaneous forming of polymerized vesivles and replace liposomes from unspontaneous fabrication as drug carriers.
The porous polymers-high oil-absorption resins were prepared by microemulsion polymerization, and the microemulsions come from polymerizable surfactant - Sodium Dodecyl Allyl Sulfosuccinic Diester (SDASD) as emulsioner. the three sub-structures of the micromulsion were determined with conductivity. At the same time, the effect of the weight ratios of MAA to LMA and the quality percentage of SDASD aqueous solution on the phase region was also studied. We also studied the influences of the kinds and ratio of monomer, temperature of polymerization and dosage of crosslinker on oil-absorption rate and absorbing speed of the resin, and the optimum cindtions were obtained. The high oil-absorption resins which were prepared at the optimum cindtions had an excellent effect of oil absorption of 7.9g(gasoline)/g(resin). It is because polymerizable surfactants were used as emulsioner of microemulsion polymerization that phenomenon of phase separation had decreased and the structures of the resins were easy to control and a new idea came into being for preparation of high oil-absorption resin.
Taking SDASD as emulsioner, transparent porous polymers were prepared by ionic liquid instead of water, and with conductivity three microstructure of the single-phase microemulsion as well as area of [bmim] [BF_4] / acrylate (methacrylate / n-butyl), bicontinuous phase and acrylate / [bmim] [BF_4] were further defined. Effects of sub- structures of the micromulsion, enter of water in bicontinuous phase, dispose method of polymer on structures of hole, and transparence of polymers were also discussed. Then the optimum condtions were obtained by ionic liquid microemulsion polymerization to prepare transparent porous polymers at optimum weight ratios. It is because polymerizanle surfactant and ionic liquid were introduced that phenomenon of phase separation had decreased in microemulsion polymerization and the transparence and porosity of polymers were enhanced. We have obtained great progress in keeping microemulsion with ideal structure brfore polymerization and enriched ways and means of preparation of transparent porous polymers.
设计并合成了结构新型的可聚合表面活性剂——烷基烯丙基琥珀酸双酯磺酸钠系列产物,并对其结构进行了确证,对其表面性能进行了测试,为乳液聚合、微乳液聚合的应用以及聚合囊泡等可聚合有序聚集体的构建提供了新的可聚合表面活性剂品种。
以十四烷基烯丙基琥珀酸酯磺酸钠(STASD)和十六烷基三甲基溴化铵(CTAB)配制可聚合囊泡,对囊泡聚合前后的稳定性及影响因素进行了研究。得出采用过硫酸铵(APS)作引发剂,在80℃下聚合1.5小时的样品经过~1HNMR判断囊泡中双键的转化率为3.14%,该样品在常温下可稳定存放8个月,而一般囊泡只能存放3周左右,经聚合后的囊泡稳定性大大提高。在国内,首次利用可聚合表面活性剂制备的聚合囊泡用于药物载体研究,聚合囊泡对阿司匹林的包封率比未聚合囊泡高15~20%。50小时检测期内,在模拟肠液中,未聚合囊泡中阿司匹林释放率达79%左右,聚合囊泡释放率仅为29%左右;在模拟胃液中,未聚合囊泡中阿司匹林释放率达56%左右,聚合囊泡释放率仅为23%左右。相比于未聚合囊泡,聚合囊泡对阿司匹林有非常明显的缓释效果。这些研究开创了自发形成聚合囊泡和取代非自发制备脂质体作为药物载体的先河。
采用十二烷基烯丙基琥珀酸酯磺酸钠(SDASD)做乳化剂制备微乳液,并用该体系制备多孔聚合物——高吸油性树脂。利用电导率法确定了微乳液的三种亚结构,同时考察了m(MAA)/m(LMA)和SDASD的质量百分含量对微乳液区域大小的影响。详细探讨了微乳液的双连续区域、单体种类及配比、聚合温度、交联剂用量等工艺因素对合成树脂的吸油率和吸油速率的影响,得出最佳聚合工艺条件,在最优工艺条件下制得的树脂吸油效果为7.9g/g(以汽油计)。可聚合表面活性剂的应用减少了微乳聚合过程中相分离的发生,树脂的孔结构易于调控,为高吸油性树脂的制备提供了一种新的思路。
利用SDASD做乳化剂,采用离子液体代替水制备微乳液并用该体系制备透明多孔聚合物,用电导法确定了单相微乳液区存在[bmim] [BF_4] /丙烯酸酯、双连续相、丙烯酸酯/ [bmim][BF_4]三种亚结构。探讨了微乳液亚结构类型、双连续相中水的加入、聚合产物的后处理方法对聚合物的孔结构和透明性的影响。然后在最佳质量配比下进行最佳工艺条件的探究,得出离子液体微乳液聚合制备丙烯酸酯透明多孔聚合物的最佳工艺条件。可聚合表面活性剂和离子液体的引入减少了微乳聚合中相分离的发生和增加了产物的透明性和多孔性。这些研究使微乳液聚合在保持聚合前的理想结构方面取得了进展,丰富了透明多孔聚合物的制备方法。
Ordered self-assemblies of surfactants have been widely and successfully used in the fields of life science, medicine, energy, material science, etc. Unfortunately, the self-assemblies are often formed owing to the interactions of surfactants molecules. The microstructures of aggregates are often changed with environment conditions such as consistence, ion intensity, temperature and so on. Thus, improving the stability of self-assemblies has been a hot topic recently. If polymerizable surfactants are employed to fabricat ordered self-assemblies and these structures are fixed by polymerization, then stability of the ordered self-assemblies will be efficiently improved.
A series of novel polymerizable surfactants - Sodium Alkyl Allyl Sulfosuccinic Diesters were designed and synthesized in this work. The structures of all products were determined by IR and ~1HNMR. The surface properties were also tested. This provied new polymerizable surfactants for emulsion and microemulsion polymerization and polymerizable ordered self-assemblies such as polymerized vesicles.
Polymerized vesicles were prepared spontaneously from aqueous mixtures of polymerizable surfactant - Sodium Tetradecyl Allyl Sulfosuccinic Diester (STASD) and Cetyl Trimethyl Ammonium Bromide (CTAB). The stability of the vesicles against salts, ethanol, temperature, and staying time was studied before and after polymerization. Adopting APS as initiator, double bond of the vesicles which polymerized for 1.5 h at 80℃had translated 3.14% by ~1HNMR. The polymerized vesicles could be preserved for eight months and the unpolymerized vesicles for three weeks at normal temperature. It was found that stability of the vesicles was markedly enhanced after polymerization. We firstly applied the polymerized vesicles formed from polymerizable surfactants as drug carriers. The encapsulation efficiency of the polymerized vesicles for aspirin was 15~20% higher than the unpolymerized vesicles. During 50 h , the release ratio the polymerized vesicles was about 79% , but the unpolymerized vesicles was about 29% in simulated intestinal fluid , and the release ratio the polymerized vesicles was about 56%, but the unpolymerized vesicles was about 23% in simulated gastric fluid .Compared with unpolymerized vesicles, the polymerized vesicles have higher encapsulation efficiency and distinctly slow release effects for encapsulated aspirin. All the results lead spontaneous forming of polymerized vesivles and replace liposomes from unspontaneous fabrication as drug carriers.
The porous polymers-high oil-absorption resins were prepared by microemulsion polymerization, and the microemulsions come from polymerizable surfactant - Sodium Dodecyl Allyl Sulfosuccinic Diester (SDASD) as emulsioner. the three sub-structures of the micromulsion were determined with conductivity. At the same time, the effect of the weight ratios of MAA to LMA and the quality percentage of SDASD aqueous solution on the phase region was also studied. We also studied the influences of the kinds and ratio of monomer, temperature of polymerization and dosage of crosslinker on oil-absorption rate and absorbing speed of the resin, and the optimum cindtions were obtained. The high oil-absorption resins which were prepared at the optimum cindtions had an excellent effect of oil absorption of 7.9g(gasoline)/g(resin). It is because polymerizable surfactants were used as emulsioner of microemulsion polymerization that phenomenon of phase separation had decreased and the structures of the resins were easy to control and a new idea came into being for preparation of high oil-absorption resin.
Taking SDASD as emulsioner, transparent porous polymers were prepared by ionic liquid instead of water, and with conductivity three microstructure of the single-phase microemulsion as well as area of [bmim] [BF_4] / acrylate (methacrylate / n-butyl), bicontinuous phase and acrylate / [bmim] [BF_4] were further defined. Effects of sub- structures of the micromulsion, enter of water in bicontinuous phase, dispose method of polymer on structures of hole, and transparence of polymers were also discussed. Then the optimum condtions were obtained by ionic liquid microemulsion polymerization to prepare transparent porous polymers at optimum weight ratios. It is because polymerizanle surfactant and ionic liquid were introduced that phenomenon of phase separation had decreased in microemulsion polymerization and the transparence and porosity of polymers were enhanced. We have obtained great progress in keeping microemulsion with ideal structure brfore polymerization and enriched ways and means of preparation of transparent porous polymers.
引文
[1] Winsor P A. Binary and multicomponent solutions of amphiphilic compounds Solublization and the formation, structure, and theoretical significance of liquid crystal solutions [J]. Chem Rev, 1968, 68: 1-40
[2]朱步瑶,赵振国.界面化学基础[M].北京:化学工业出版社, 1996
[3]赵国玺.表面活性剂物理化学[M]. 2版.北京:北京大学出版社, 1991
[4]赵国玺,朱步瑶.表面活性剂作用原理[M].北京:中国轻工业出版社, 2003
[5] Hoffmann M M, Heitz M P, Carr J B, et al. Surfactants in green solvent systems - Current and future research directions [J]. J Dispersion Sci Technol, 2003, 24(2): 155-171
[6]韩峰,清洁介质中表面活性剂分子聚集体的构建[D].武汉:武汉工业学院, 2008
[7]张国栋,陈晓,靖波.室温离子液体中的有序分子组合体[J].化学进展, 2006, 18: 1085-1091
[8] Hao J C, Zemb T. Self-assembled structures and chemical reactions in room-temperature ionic liquids [J]. Curr Opin Colloid Interface Sci, 2007, 12: 129-137
[9]高艳安.在绿色溶剂中超分子结构研究—微乳液,环糊精与离子液包容相互作用[D].济南:山东大学, 2005
[10] Fendler J H. Polymerized surfactant vesicles: novel membrane mimetic systems [J]. Science, 1984, 223: 888-894
[11] Gros L, Ringsdorf H, Schupp H. Polymeric antitumor agents on a molecular and on a cellular level [J] Angew Chem, Int Ed Engl. 1981, 20: 305-325
[12] Paleos C M. Polymerization in organized systems [J]. Chem Soc Rev.1985, 45:45-66.
[13] Bader H, Dorn K, Hupfer B, et al. Polymeric monolayers and liposomes as models for biomembranes -How to bridge the gap between polymer science and membrane biology [J]. Adv Polym Sci, 1985, 64: 1-62
[14] Regen S L. Polymerized liposomes [M]. New York, Marcel Dekker, 1987: 73-108
[15] Ringsdorf H, Schlarb B, Venzmer J. Molecular architecture and function of polymeric oriented systems: models for the study of organization, surface recognition, and dynamics of biomembranes [J]. Angew Chem, Int Ed Engl, 1988, 27(1): 113-158
[16] O’Brien D F, Ramaswami V. Polymerized vesicles [J]. Encycl Polym Sci Eng, 1989, 17: 108-135
[17] Singh A, Schnur J M.. Polymerizable phospholipids [M]. New York, Marcel Dekker,1993: 233-291
[18] Singh A, Markowitz M, Chow G M. Materials fabrication via polymerizable self-organized membranes: an overview [J]. NanoStructured Materials, 1995, 5(2): 141-153
[19] O’Brien D F, Armitage B, Benedicto A, et al. Polymerization of preformed self-organized assemblies[J]. Acc Chem Res, 1998, 31(12): 861-868
[20] Miller S A, Ding J H, Gin D L. Nanostructured materials based on polymerizable amphiphiles[J]. Curr Opin Colloid Interface Sci, 1999, 4(5):338-347
[21] Keisuke Tajima, Takuzo Aida. Controlled polymerizations with constrained geometries [J]. Chem Commum, 2000, 2399-2412
[22] Hubert D H W, Jung M, German A L. Vesicles templating [J]. Adv Mater, 2000, 12: 1291-1294
[23] Mueller A, O’Brien D F. Supramolecular materials via polymerization of mesophases of hydrated amphiphiles [J]. Chem Rev, 2002, 102(3): 727-757
[24] Hentze H P, Kaler E W. Polymerization of and within self-organized media [J]. Curr Opin Colloid Interface Sci, 2003, 8: 164-178
[25] Summers M, Eastoe J. Applications of polymerizable surfactants [J]. Adv Colloid Interface Sci, 2003, 100-102: 137-152
[26] Yan Feng, John Texter. polymerization of and in mesophases[J]. Adv Colloid Interface Sci, 2006, 128-130: 27-35
[27] Mattew P C, Timothy E L. Biomimetic design and performance of polymerizable lipids [J]. Acc Chem Res, 2009, 42(8):1016-1025
[28] Merrigan T L,Bates E D, Dorman S C. New fluorous ionic liquids function as surfactants in conventional room-temperature ionic liquids [J]. Chem Commun, 2000, 2051-2052
[29] Kimizuka N, Nakashima T. Spontaneous self-assembly of glycolipid bilayer membranes in sugar– philic ionic liquids and formation of ionogels [J]. Langmuir, 2001, 17(22): 6759-6761
[30] Hoefling T A, Enick R M E, Beckman E J. Microemulsions in near-critical and supercritical carbon dioxide [J]. J Phys Chem, 1991, 95: 7127-7129
[31] Zemb T, Duboism, Deme B, et a.l. Self-assembly of flatnanodiscs in salt-free catanionic surfactant solutions [J]. Science, 1999, 283: 816-819
[32] Duboism, Deme B, Gulikkrzywickit, et al. Self-assembly of regular hollow icosahedra in salt-free catanionic solutions [J]. Nature, 2001, 411: 672-675
[33]姜文清,郝京诚.水相和特殊介质中有序聚集体的结构、性质和应用(1) [J].日用化学工业, 2008, 38(4): 257-266
[34].Israelachvili J N, Mitchell D J, Ninham B W. Theory of selfassembly of hydrocarbon amphiphiles into micelles and bilayers [J]. J Chem Soc, Faraday TransⅡ, 1976, 72: 1525-1568
[35] Winterhalter M, Helfrich W. Bending elasticity of electrically charged bilayers: coupled monolayers, neutral surfaces, and balancing stresses [J]. J Phys Chem, 1992, 96(1): 327-330
[36] Leng J, Egelhaaf S U, Cates M E. Kinetics of the micelle-to-vesicle transition: Aqueous lecithin- bile salt mixtures [J]. Biophysical Journal, 2003, 85: 1624–1646
[37] Rusanov A I. Thermodynamics of vesicles [J]. Colloids and Surfaces A, 1993,76: 7-13
[38] Leermakers F A M, Scheutjens J M H M. Statistical thermodynamics of association colloids : lipid vesicles [J]. J Phys Chem, 1989, 93(21):7417-7426
[39] Safran S A, Pincus P, Andelman D. Theory of spontaneous vesicle formation in surfactant mixtures [J]. Science, 1990, 248(4953): 354-356
[40] Freedman H H, Mason J P, Medalia A I. Polysoaps:ⅡThe preparation of vinyl soaps [J]. J Org Chem, 1958, 23(1): 76-82
[41] Holmberg K. Polymerizable surfactants [J]. Prog Org Coat, 1992, 20(3-4): 325-337
[42] Digioia F A, Nelson R E. Freeze -Thaw studies of latex paint polymers[J]. Ind Eng Chem, 1953, 45(4): 745-748
[43] Kronberg B, Kuortti J, Stenius P. Competitive and cooperative adsorption of polymers and surfactants on kaolinite surfaces [J]. Colloids Surf A, 1986, 18(2-4): 411-425
[44] Hulden M, Sjoblom E. Adsorption of some common surfactants and polymers on TiO2-pigments [J]. Prog Colloid Polym Sci, 1990, 82: 28–37
[45] Evanson K W, Urban M W. Surface and interfacial FTIR spectroscopic studies of latexes. I. Surfactant– copolymer interactions [J]. J Appl Polym Sci, 1991, 42(8): 2287–2296
[46] Evanson K W, Thorstenson T A, Urban M W. Surface and interfacial FTIR spectroscopic studies of latexes II Surfactant–copolymer compatibility and mobility of surfactants [J]. J Appl Polym Sci, 1991, 42(8): 2297–2307
[47] Guyot A, Tauer K. Reactive surfactants in emulsion polymerization [J]. Adv Polym Sci, 1994, 111: 43–65
[48] Guyot A. Advances in reactive surfactants [J]. Adv Colloid Interface Sci, 2004, 108-109: 3-22
[49] Soula O, Guyot A, Williams N, et al. Styrenic surfmer in emulsion copolymerization ofacrylic monomers II Copolymerization and film properties [J]. J Polym Sci, Part A: Polym Chem, 1999, 37 (22): 4205–4217
[50] Sindt O, Gauthier C, Hamaide T, et al. Reactive surfactants in heterophase polymerization. XVI. Emulsion copolymerization of styrene–butyl acrylate–acrylic acid in the presence of simple maleate reactive surfactants [J]. J Appl Polym Sci , 2000, 77(12): 2768–2776
[51] UnzuéM J, Schoonbrood H A S, Asua J M, et al. Reactive surfactants in heterophase polymerization VI Synthesis and screening of polymerizable surfactants (surfmers) with varying reactivity in high solids styrene-butyl acrylate-acrylic acid emulsion polymerization [J]. J Appl Polym.Sci, 1997, 66(9): 1803–1819
[52] Aramendia E, Mallégol J, Jeynes C, et al. Distribution of surfactants near acrylic latex film surfaces: A comparison of conventional and reactive surfactants (Surfmers) [J]. Langmuir, 2003, 19(8): 3212-3221
[53] Yokota K, Ichihara A, Shinike H. Surfactant [P]. US: 5 324 862, 1994
[54] Aramendia E, Barandiaran M J, Grade J, et al. Improving water sensitivity in acrylic films using surfmers [J]. Langmuir, 2005, 21(4): 1428-1435
[55] Abele S, Gauthier C, Graillat C, et al. Films from styrene–butyl acrylate lattices using maleic or succinic surfactants: mechanical properties, water rebound and grafting of the surfactants [J]. Polymer, 2000, 41(3): 1147–1155
[56] Amalvy J I, Unzue M J, Schoonbrood H A S, et al. Reactive surfactants in heterophase polymerization: Colloidal properties, film-water absorption, and surfactant exudation [J]. J Polym Sci, Part A: Polym. Chem, 2002, 40(17): 2994–3000
[57] Greene B W, Sheetz D P, Filer T D. In situ polymerization of surface-active agents on latex particles I. Preparation and characterization of styrene/butadiene latexes [J]. J Colloid Interface Sci, 1970, 32(1): 90–95
[58] Greene B W, Sheetz D P. In situ polymerization of surface-active agents on latex particles II. The mechanical stability of styrene/butadiene latexes [J]. J Colloid Interface Sci, 1970, 32(1): 96–105
[59] Guyot A. Recent progress in reactive surfactants in emulsion polymerisation [A]. Macromol Symp, 2002, 179:105-132
[60] Asua J M, Schoonbrood H A S. Reactive surfactants in heterophase polymerization[J]. Acta Polym, 1998, 49(12): 671-686
[61]朱明月,乔卫红,毕晨光等.乳液聚合中的可聚合乳化剂研究进展[J].化工进展,2006, 25(5): 490-494
[62]熊娉婷,鲁德平,黄宏志.可聚合表面活性剂的研究进展[J].高分子通报, 2006,(8): 14-20
[63] Stoffer J O, Bone T. Polymerization in water in oil microemulsion systems containing methyl methacrylate [J], J Dispersion Sci Technol, 1980, 1: 393-398
[64] Stoffer J O, Bone T. Polymerization in water-in-oil microemulsion systems I [J]. J Polym Sci Polym Chem Ed, 1980, 18(8): 2641-2648
[65] Atik S S, Thomas K J. Polymerized microemulsions[J]. J Am Chem Soc, 1981, 103(14): 4279-4280
[66] Atik S S, Thomas K J. Photochemistry in polymerized microemulsion systems[J]. J Am Chem Soc,1982, 104(22): 5868-5874
[67] Gan L M, Chew C H. Polymerization in the transparent water-in-oil solutions I: Methyl methacrylate and the copolymerizable cosurfactant [J]. J Dispersion Sci Technol, 1983, 4(3): 291-312
[68] Gan L M, Li T D, Chew C H, et al. Porous polymeric materials from cationic microemulsions [J]. Journal of Macromolecular Science, Part A, 1995, 32(5): 969-980
[69] Gan L M, Li T D, Chew C H, et al. Preparation of ultrafiltration membranes by direct microemulsion polymerization using polymerizable surfactants [J]. Langmuir, 1996, 12(24): 5863-5868
[70] Gan L M, Chieng t H, Chew C H, et al. Microstructural control of porous polymeric materials via a microemulsion pathway using mixed nonpolymerizable and polymerizable anionic surfactants [J]. Langmuir, 1996, 12(2): 319-324
[71] Chew C H, Li T D, Gan L H, et al. Bicontinuous-nanostructured polymeric materials from microemulsion polymerization [J]. Langmuir, 1998, 14(21): 6068-6076
[72] Xu W, Siow K S, Gao Z, et al. Microporous polymeric composite electrolytes from microemulsion polymerization [J]. Langmuir, 1999, 15(14): 4812-4819
[73] Ong C L, Gan L M, Ong C K, et al. Unusual ionic behavior in microemulsion- polymerized membranes [J]. J Phys Chem B, 1999, 103(36): 7573-7576
[74] Chow P Y, Chew C H, Ong C L, et al. Ion-containing membranes from microemulsion polymerization [J]. Langmuir, 1999, 15(9): 3202-3205
[75] Fendier J H, Tundo P. Polymerized surfactant aggregates-characterization and utilization[J]. Acc Chem Res, 1984, 17(1): 3-8
[76]张洪涛,任天斌.可聚合乳化剂的种类及乳液聚合[J].粘接, 1999, (2): 26-28; 1999,(3): 33-36
[77]彭顺金,张贵军,方华,等.反应性乳化剂及其乳液聚合[J].涂料工业, 1999, (5): 36-39
[78]任天斌,张洪涛.可聚合表面活性剂的类型及应用[J] .日用化学工业, 2000, 30(3): 25-28
[79] Varuni Subramaniam. Preparation and characterization of novel lipid and proteolipid membranes from polymerizable lipids [D]. The University of Arizona, 2007: 53
[80]孙彦,刘敬义,于凯,等.聚合脂质体[J].有机化学, 1994, 14(5): 468-479
[81]于网林,赵国玺.囊泡的形成与两亲分子结构[J].化学通报, 1996, 6: 21-25
[82] Fendler J H. Membrane mimetic chemistry(膜模拟化学)[M].程虎民,高月英译,北京:科学出版社, 1991
[83] Schulman J H, Stoeckenius W, Prince L M. Mechanism of formation and structure of microemulsions by electron microscopy [J]. J Phy Chem, 1959, 63 (10): 1677-1680
[84] Bangham A D, Standdish M M, Watkins J. Difusion of univalent ions across the lamellae of swollen phospholipids [J]. J Mol Biol, 1965, 13: 238-242
[85] Kunitake T, Okahata Y A. Totally synthetic bilayer membrane [J]. J Am Chem Soc. 1977, 79: 3860-3861
[86] Talmon Y, Evans D F, Ninham B W. Spontaneous vesicles formed from hydroxide surfactants: evidence from electron microscopy [J]. Science, Newseries, 1983, 221(4615): 1047-1048
[87] Brady J E, Evans D F, Kachar B, et al. Spontaneous vesicles [J]. J Am Chem Soc, 1984, 106(15): 4279-4280
[88] Lin Z, He M, Scriven L E, et al. Vesicle formation in electrolyte solutions of a new cationic siloxane surfactant [J]. J Phys Chem, 1993, 97(14): 3571-3578
[89] Kaler E W, Murthy A K, Rodriguez B E, et al. Spontaneous vesicle formation in aqueous mixtures of single-tailed surfactants [J]. Science, NewSeries, 1989, 245(4924): 1371 - 1374
[90] Herrington K L, Kaler E W. Phase behavior of aqueous mixtures of dodecyl- trimethyl ammonium bromide(DTAB) and sodium dodecyl sulfate(SDS) [J]. J Phys Chem, 1993, 97: 13792-13802
[91] Kaler E W, Herrington K L, Murthy A K. Phase behavior and structures of mixtures of and cationic surfactants [J]. J Phys Chem, 1992, 96: 6698-6707
[92] Yuet P K, Blankschtein D. Effect of surfactant tail-length asymetry on the formation ofmixed surfactant vesicles [J]. Langmuir, 1996, 12:3819-3827
[93] Lasic D D, Joannic R, Keller B C, et al. Spontaneous vesiculation [J]. Adv in Coll Interf Sci, 2001, 89: 337-349
[94] Tondre C, Caillet C. Properties of the amphiphilic films in mixed cationic/anionic vesicles: a comprehensive view from a literature analysis [J]. Adv in Coll Interf Sci, 2001, 93: 115-134
[95] Marques E F, Regev O, Khan A, et al. Vesicle formation and general phase behavior in the catanionic mixture SDS-DDAB-water,the cationic-rich side [J]. J Phys Chem B, 1999, 103(39): 8353-8363
[96] Hofland H E J, Bouwstra J A, Gooris G S, et al. Nonionic surfactant vesicles:A study of vesicle formation,characterization,and stability [J]. J Coll Interf Sci, 1993, 161: 366-376
[97]陈文君,翟利民,李干佐,等.囊泡的自发形成-两类表面活性剂复配[J].科学通报, 2003, 6(48): 562-566
[98] Zhai L M, Li G Z, Sun Z W. Spontaneous vesicle formation in aqueous solution of zwitterionic and anionic surfactant mixture [J]. Colloids and Surfaces A, 2001, 190: 275-283
[99] Bergmerier M, Hoffmann H, Witte F, et al. Vesicles from single-chain hydrocarbon surfactants and perfluoro cosurfactants [J]. J Colloid Interface Sci, 1998, 203(1): 1-15
[100] Hao J C, Hoffmann H. Self-assembled structures in excess and salt-free catanionic surfactant solutions [J]. Curr Opin Colloid Inter Sci, 2004, 9: 279-293
[101] Wang J Z, Song A X, Jia X F, et al. Two routes to vesicle formation:Metal-ligand complexation and ionic interactions [J]. J Phys Chem B, 2005, 109(22): 11126-11134
[102] Hargreaves W R, Deamer D W. Liposomes from ionic, Single-chain amphiphiles [J]. Biochemistry, 1978, 17(18): 3759-3768
[103]赵国玺,黄建滨.表面活性剂混合物水溶液中的囊泡形成[J].物理化学学报, 1992, 8(5): 583-585
[104] Zhao G X, Yu W L. Vesicles from mixed sodium 10-Undecenoate- Decyltrimeth- ylammonium Bromide solutions [J]. J Coll Interface Sci, 1995, 173: 159-164
[105] Jung H T, Coldren B, Zasadzinski J A, et al. The origins of stability of spontaneous vesicles [A]. Proceedings of the National Academy of Sciences of the United States of America, 2001, 98(4): 1353-1357
[106] Liu S Y, Gonzalez Y I, Kaler E W. Structural fixation of spontaneous vesicler in aqueous mixtures of polymerizable anionic and cationic surfacants [J]. Langmuir, 2003,19: 10732-10738
[107] Wang X Y, Zeng GM, Wang Y L, et al. Salt effect on polymerizable vesicles of allyl dodecyl dimethylammonium bromide and sodium dodecyl sulfonate in aqueous solution [J]. Chinese Journal of Chemistry, 2008, 26: 439-444
[108] Hotz J, Meier W. Vesicle-Templated polymer hollow spheres [J]. Langmuir, 1998, 14(5): 1031-1036
[109] Kurja J, Nolte R J M, Maxwell I A, et al. Free radical polymerization of styrene in dioctadecyl dimethylammonium bromide vesicles [J]. Polymer, 1993, 34: 2045-2049
[110] Jung M, Hubert D H W, Bomans P H H, et al. New Vesicle-Polymer hybrids:The parachute architecture [J]. Langmuir, 1997, 13(26): 6877
[111] Poulain N, Nakache E, Pina A, et al. Nanoparticles from vesicle polymerization: characterization and kinetic study [J]. J Polym Sci Part A:Polym Chem, 1996, 34(5): 729-737
[112] Morgan J D, Johnson C A, Kaler E W. Polymerization of equilibrium vesicles [J]. Langmuir, 1997, 13(24): 6447-6451
[113] McKelvey C A, Kaler E W, Zasadzinski J A, et al. Templating hollow polymeric spheres from catanionic equilibrium vesicles:Synthesis and characterization [J]. Langmuir, 2000, 16(22): 8285-8290
[114] Krafft M P, Schieldknecht L, Marie P, et al. Fluorinated vesicles allow intrabilayer polymerization of a hydrophobic monomer,yielding polymerized microcapsules [J]. Langmuir, 2001, 17(9): 2872-2877
[115] Song L Y, Ge X W, Wang M Z, et al. Anionic/nonionic mixed surfactants templates preparation of hollow polymer spheres via emulsion polymerization [J]. J Polym Sci Part A:Polym Chem, 2006, 44(8): 2533-2541
[116]余娜,孙丹,韩兆让. CTAB/SDBS囊泡的自发形成与聚合[J].化学学报, 2008, 66(3): 315-320
[117] Lawrence M J. Surfactant systems: Microemulsions and vesicles as vehicles for drug delivery [J]. Eur J Drug Metab Pharmacokinet, 1994, 19(3): 257-269
[118] Discher D E, Eisenberg A. Polymer vesicles [J]. Science, 2002, 297: 967-973
[119] Liu S C, O'Brien D F. Cross-linking polymerization in two-dimensional assemblies: Effect of the reactive group site [J]. Macromolecules, 1999, 32(17): 5519-5524
[120] Neumann R, Ringsdorf H. Peptide liposomes from amphiphilic Amino-Acids [J]. J Am Chem Soc, 1986, 108(3): 487-490
[121] Neumann R. Preparation and characterization of long-chain Amino-Acid and peptidevesicle membranes [J]. Biochimica Et Biophysica Acta, 1987, 898(3): 338-348
[122] Marques E F. Size and Stability of Catanionic vesicles:Effects of formation path, sonication, and aging [J]. Langmuir, 2000, 16: 4798-4807
[123] Walker S A, Zasadzinski J A. Electrostatic control of spontaneous vesicle aggregation [J]. Langmuir, 1997, 13: 5076-5081
[124] Sun S T, Day E P, Ho J T. Temperature dependence of calcium-induced fusion of sonicated phosphatidylserine vesicles[A]. Proc Natl Acad Sci USA,1978, 75(9): 4325-4328
[125] Sun S T, Hsang C C, Day E P,et al. Fusion of phosphatidylserine and mixed phosphatidylserine- phosphatidylcholine vesicles: Dependence on calcium concentration and temperature [J]. Biochimica et Biophysica Acta (BBA) - Biomembranes, 1979, 557(1): 45-52
[126]韩峰,付宏兰,何潇,等.正负离子表面活性剂混合体系中高稳定性囊泡的形成[J].化学学报, 2003, 61(9): 1399-1404
[127]韩秀梅.氟碳型表面活性剂的合成及囊泡的稳定性、包覆性能的研究[D].东北师范大学, 2001
[128]孙丹.囊泡的稳定性与其在制备聚合物中空微球中的应用研究[D].吉林:吉林大学, 2008
[129]余娜.囊泡的自发形成与其稳定性的研究[D].吉林:吉林大学, 2007
[130]于网林表面活性剂分子有序组合体的研究[D].北京:北京大学, 1995
[131]黄建滨,赵国玺.正负离子表面活性剂混合溶液中囊泡的稳定性[J].北京大学学报(自然科学版), 1999, 35(2): 144-150
[132]尹海清.阴阳离子表面活性剂混合体系中有序组合体的调控[D].北京:北京大学, 2006
[133]周文婷,徐晓明,蓝琴,等.囊泡形成和破坏的动力学[J].化学学报, 2007, 65(20): 2279-2284
[134] Regen S L, Czech B, Singh A. Polymerized vesicles [J]. J Am Chem Soc, 1980, 102(21): 6638-6640
[135] Hub H H, Hupfer B, Koch H, et al. Polyreaction in ordered systems 20: polymerizable phospholipid analogs-new stable biomembrane and cell models [J]. Angew Chem Int Edit, 1980, 19(11): 938-940
[136] Tundo P, Kippenberger D J, Klahn P L, et al. Functionally polymerized surfactantvesicles–synthesis and characterization [J]. J Am Chem Soc, 1982, 104(2): 456-461
[137] Tundo P, Kurihara K, Kippenberger D J, et al. Chemically dissymmetrical polymerized surfactant vesicles–synthesis and possible utilization in artificial photosynthesis [J]. Angew Chem Int Edit 1982, 21(1): 81-82
[138] Hub H H, Hupfer B, Ringsdorf H. Polymerization of lipid and lysolipid-like diacetylenes in monolayers and liposomes [J]. Am Chem Soc Coat Plast Chem, 1980, 42: 2-7
[139] Hub H H, Hupfer B, Koch H, et al. Polymerization of lipid and lysolipid-like diacetylenes in monolayers and liposomes [J]. J Macromol Sci Chem A, 1981, 15: 701-715
[140] JohnSton D S, Sanghera S, Manjon-Rubio A, et al. The formation of polymeric model biomembranes from diacetylenic fatty acids and phospholipids [J]. Biochim Biophys Acta, 1980, 602: 213-216
[141] John Ston D S, Sanghera S, Pons M, et al. Phospholipid, polymers-synthesis and spectral characteristics [J]. Biochim Biophys Acta, 1980, 602: 57-69
[142] Akimoto A, Dorn K, Gross L, et al. Polymer model membranes [J]. Angew Chem Int Ed Eng, 1981, 20: 90-91
[143] Bader H, Ringsdorf H, Skura J. Liposomes from polymerizable Glycolipids [J]. Angew Chem Int Ed Eng, 1981, 20: 91-92
[144] Gros L , Ringsdorf H , Schupp H. Polymeric antitumor agents on a molecular and on a cellular level [J]. Angew Chem Int Ed Eng, 1981, 20: 305-325
[145] Kunitake T, Nakashima N, Takarabe K, et al. Vesicles of polymeric bilayer and monolayer membranes [J]. J Am Chem Soc, 1981, 103(19): 5945-5947
[146] Lopez E, O’Brien D F, Whitesides T H. Structural effect on the photopolymerization of bilayer membranes [J]. J Am Chem Soc, 1982, 104: 305-307
[147] Regen S L, Singh A, Oehme G, et al. Polymerized phosphatidyl choline vesicles, stabilized and controllable time-release carriers [J]. J Am Chem Soc, 1981, 103:
[148] Tundo P, Prieto N E, Kippenberger D J, et al. Redox active functionally polymerized surfacetant vesicles, synthesis and characterization [J]. J Am Chem Soc, 1982, 104: 5352-5358
[149] Tundo P, Kurihara K, Prieto N E, et al. Chemically dissymmetyical polymerized surfacetant vesicles. synthesis and utilization in artificial photosynthesis [J]. J Am Chem Soc, 1982, 103:
[150] Fendler J H. Polymerized surfactant Vesicles: Novel membrane mimetic systems [J].Science, 1984, 223: 888-894
[151] Fendler J H. Membrane-mimetic approach to advanced materials (尖端材料的膜模拟) [M].江龙等译,北京:科学出版社, 1999
[152]方一非,容寿榆.双棕榈酰磷脂酰胆碱-聚-α-桐酸脂质体[J].科学通报, 1986,(17): 1338-1341
[153] Fang Y F. The polymerization ofα-Eleostearic Acid in the Dipalmitoyl- phosphatidylcholine -α-Eleostearic Acid liposome [J]. Chinese Journal of polymer Science, 1987, 5(4): 346-352
[154] Li Z C, Xie X M, Fan Q H, et al. Polyeleostearic Acid vesicles [J]. Chinese Journal of Polymer Science, 1992, 10(1): 26-31
[155]李子臣,何巍,李福绵.可聚合脂质体的研究Ⅱ-含桐酸脂质体的稳定性和穿透能力的研究[J].高分子学报, 1995, (2): 238-241
[156]李子臣.双分子层脂质体膜的稳定,修饰及性质研究[D].北京:北京大学, 1994
[157]张立群,周洪兵,周晴中,等.脂质体的聚合反应(Ⅰ) -不饱和脂质体的单体合成[J].高等学校化学学报, 1990, 11(9): 1034-1036
[158]李子臣,何巍,李福绵.可聚合脂质体的研究Ⅰ-含共轭双炔基团的两亲性单体及其脂质体[J].高分子学报, 1995, (1): 113-16
[159]于凯,孙彦,张宝申,等.共轭二炔结构类脂化合物的合成及其聚合脂质体的制备和稳定性研究[J].高等学校化学学报, 1996, 17(3): 392-395
[160]于凯.功能化聚合脂质体的合成,制备及性质[D].天津:南开大学, 1993
[161]李小奎,陈忠秀,郭纲敏,等.聚联乙炔变色囊泡技术构建及在食品安全快速检测中的应用[J].食品科技, 2010, 35(7): 303-307
[162]何巍,李子臣,李福绵.可聚合脂质体的研究Ⅲ-可缩聚氨基酸类双亲分子的合成及其脂质体[J].高分子学报, 1996, (5):615-617
[163]余作兴,赵德仁.高分子微泡的研究Ⅰ-二烯丙基二(十二烷基)季铵盐的合成与聚合[J].功能高分子学报, 1988, 1(1): 39-45
[164]陈志良,管爱国,赵德仁.高分子微泡的研究Ⅲ-二烯丙基二(十八烷基)溴化铵的制备与聚合[J].功能高分子学报, 1996, 9(3): 364-370
[165]王湘英.两亲分子聚合囊泡的合成及其对有机污染物的增溶行为[D].长沙:湖南大学, 2008
[166] Moss R A, Swarup S. Transvesicular reactions of thiols with ellman's reagent [J]. J OrgChem, 1988, 53(25): 5860-5866
[167] Fendler J H, Hinze W L. Reactivity control in micelles and surfactant vesicles. Kinetics and mechanism of base-catalyzed hydrolysis of 5,5'-dithiobis(2-nitrobenzoic acid)in Water, Hexadecyltrimethylammonium Bromide micelles, and Dioctadecyldimethyl- ammonium Chloride surfactant vesicles [J]. J Am Chem Soc, 1981, 103(18): 5439-5447
[168] Kawamuro M K, Chaimovich H, Abuin E B, et al. Evidence that the effects of synthetic amphiphile vesicles on reaction rates depend on vesicle size [J]. J Phys Chem, 1991, 95(3): 1458-1463
[169]陈向荣,丁小斌,郑朝晖,等.聚合物纳米容器的研究进展[J].化学进展, 2004, 16(3): 370-375
[170] Hoar T P, Schulman J H. Transparent water-in-oil dispersions: the oleopathic hydro- micelle [J]. Nature, 1943, 152: 102-103
[171] Shinoda K, Friberg S. Microemulsions: colloidal aspects [J]. Adv Colloid Interface Sci, 1975, 4: 281
[172] Schulman J H, Stoeckenius W, Prince L M. Mechanism of formation and structure of micro emulsions by electron microscopy [J]. J Phys Chem, 1959, 63(10): 1677-1680
[173] Danielsson I, Lindman B. The definition of microemulsion [J]. Colloids Surface, 1981, 3: 391
[174]刘会洲.微乳相萃取技术及应用[M].北京:科学出版社, 2005: 184
[175]崔正刚,殷福珊编.微乳化技术及应用[M].北京:中国轻工业出版社, 1999
[176]李干佐,郭荣等主编.微乳液理论及应用[M].北京:石油工业出版社, 1995
[177] Klier J, Tucker C J, Kalantar T H P. Properties and applications of microemulsions [J]. Adv Mater, 2000, 12(23): 1751
[178] Stoffer J O, Bone T J. Polymerization in water in oil microemulsion systems containing methyl methacrylate [J]. Dispers Sci Technol, 1980, 1: 37
[179] Stoffer J O, Bone T J. Polymerzation in water-in-oil microemulsion systems [J]. J Polym Sci Polym Chem Ed, 1980, 18: 2641-2647
[180] Candau F, Paleos C M. Polymerization in organic media, PA: Gordon Science Publication, 1992: 215
[181] Leong Y S, Candau F. Inverse microemulsion polymerization [J]. J Chem Phys ,1982, 86(13): 2269-2271
[182] Candau F, Leong Y S, Fitch R M. Kinetic study of the polymerization of acrylamide in inverse microemulsion [J]. J Polym Sci Polym Chem Ed, 1985, 23(1): 193-214
[183] Atik S S, Thomas J K. Polymerized microemul sions [J]. J Am Chem Soc, 1981, 103(14): 4279-4280
[184] Guo J S, El Aasser M S, Vanderhoff J W. Microemulsion polymerization of styrene [J]. J Polym, Sci Polym Chem Ed, 1989, 27(2): 691-710
[185] Antonietti M, Basten R, Lohmann S. Polymerization in microemulsions - a new approach to ultrafine, highly functionalized polymer dispersions [J]. Macromol Chem Phys, 1995, 196(2): 441-466
[186] Barton J. Free-radical polymerization in inverse microemulsions [J]. Prog Polym Sci, 1996, 21(3): 399-438
[187]哈润华,侯斯健,栗付平,等.微乳液结构和丙烯酰胺反相微乳液聚合[J].高分子通报, 1995, (1): 10
[188] Carver M T, H irsch E, Wittmann J C, et al. Percolation and particle nucleation in inverse microemul sion polymerization [J]. J Phys Chem, 1989, 93(12): 4867-4873
[189] CorpartM, Candau F. Aqueous solution properties of ampholytic copolymers prepared in microemulsions [J]. Marcomolecules, 1993, 26(6): 1333-1343
[190] Candau F, Leong Y S, Pouyet G, et al. Inverse microemulsion polymerization of acrylamide: Characterization of the water- in-oil microemulsions and the final microlatexes [J]. J Colloid Interf Sci, 1984, 101(1): 167-183
[191] Carver M T, Hirsch E, Wittmann J C, et al. Percolation and particle nucleation in inverse microemulsion polymerization [J]. J Phys Chem, 1989, 93(12): 4867-4873
[192] Gan L M, Chew C H, Lee K C, et al. Formation of polystyrene nanoparticles in ternary cationic microemulsions [J]. Polymer, 1994, 35(12): 2659-2664
[193] Gan L M, Lee K C, Chew C H, et al. Growth of poly(methyl methacrylate) particles in three- component cationic microemulsions [J]. J Polym Sci, Part A: Polym Chem, 1995, 33(7): 1161-1168
[194] Gan L M, Chew C H. Polymerization of styrene in water- alcohol-ionic surfactant solutions [J]. J Macromol, Sci Chem, 1983, 19: 739
[195] Chieng T H, Gan L M, Chew C H. Microporous polymer composites form microemulsion polymerization polymerizatoin of methyl methacrylate and 2-hydroxyethyl methacrylate in microemulsions [J]. Polymer, 1995, 36(10): 1941-1946
[196] Palani Raj W R, Sasthav M, Cheung H M. Microcelluar polymeric materials from microemulsions: Control of microstructure and morphology [J]. J Appl Polym Sci, 1993, 47: 499
[197] Palani Raj W R, Sasthav M, Cheung H M. Synthesis of porous polymeric membranes by polymerization of micro-emulsions [J]. Polymer, 1993, 34(15): 3305-3312
[198] Vaskova V, H louskova Z, Barton J, et al. Polymerization in inverse microemulsions, locus of initiation by ammonium peroxodisulfate and 2,2′-azoisobutyronitrile [J]. Makromol Chem, 1992, 193(3): 627-637
[199] Potisk P, Vaskova V, Capek I, et al. Polymerization of butyl acrylate in microemulsion. Locus of initiation [J]. Angew Makromol Chem, 1996, 236(1): 43-53
[200]哈润华,侯斯健. (2-甲基丙烯酰氧乙基)三甲基氯化铵-丙烯酰胺反相微乳液共聚合[J].高等学校化学学报, 1993, 14(8): 1163-1166
[201]张志成,徐相凌,张曼维.丙烯酰胺微乳液聚合[J].高分子学报, a, 1994, (4): 426; b, 1995, (1): 23
[202]高静,李晓,张卫英,等.透明多孔聚合物凝胶的微乳液合成研究[J].石油化工, 2003, 32(7): 599-603
[203]李晓,高静,张卫英,等.微乳液聚合法制备透明丙烯酸酯多孔共聚物[J].应用化学, 2003, 20(7): 655-659
[204]何天白,胡汉杰主编.功能高分子与新技术[M].北京:化学工业出版社, 2001
[205] Nunes S P, Peinemann K V. Membrane Technology:in the Chemical Industry [M]. Wiley, 2001
[206]徐建梅,张德溶.溶胶-凝胶法的技术进展与应用现状[J].地质科技情报, 1999, 18(7): 103-106
[207] Hentze H P, Antonietti M. Template synthesis of porous organic polymers [J]. Current Opinion in Solid State and Materials Science, 2001, 5: 343-353
[208]秦振平,郭红霞.模板法合成有序多孔材料研究进展[J].化工进展, 2002, 22(5): 323-327
[209] Palani Raj W R, Sasthav M, Cheung H M. Polymerization of microstructured aqueous systems formed using methyl methacrylate and potassium undecenoate [J]. Langmuir, 1992, 8(8): 1931-1936
[210] Qutubuddin S, Haque E, Benton W J, et al. Polymer association structures: microemulsions and liquid crystals [J]. ACS Symp Ser 384, 1989, Chapter 5: 64-83
[211]王龙平.双连续相微乳液聚合法制备多孔性材料的探索研究[D].福州:福州大学, 2006
[212]薛美玲,于永良.丙烯酸酯及苯乙烯微乳体系的相行为及微乳聚合[J].应用化学,2003, (10): 11-16
[213]叶强,周炜,刘华蓉等.双连续相微乳液辐射聚合制备多孔材料的研究[J].高分子学报, 2005, (1): 40-46
[214]杨杰,舒武炳,秦卫.双连续相微乳液聚合制备多孔材料[J].功能材料, 2010, 41(1): 148-152
[215] Gan L M, Liu J, Poon L P, et al. Microporous polymeric composites from bicontinuous microemulsion polymerization using a polymerizable nonionic surfactant [J]. Polymer, 1997, 38(21): 5339-5435
[216]徐相凌,殷亚东,葛学武,等.微乳液聚合研究进展[J].高等学校化学学报, 1999, 20: 478-485
[217] Gan L M, Chew C H. W/O microemulsion of polymerizable components [J]. J Dispersion Sci Technol, 1984, 5(2): 179-191
[218] Chew C H, Gan L M. Polymerization of water-in-oil microemulsions: Methyl methacrylate acrylic acid, and sodium acrylamidostearate [J]. J Polym Sci, Polym Chem Edn, 1985, 23(8): 2225-2232
[219] Gan L M, Chew C H. Microporous polymer composites from microemulsion polymerization [J]. Colloids and Surfaces A, 1997, 123-124: 681-693
[220] Paleos C M, Stassinopoulou C I, Mallaris A. Comparative studies between monomeric and polymeric sodium 10- undecenoate micelles [J]. J Phys Chem, 1983, 87(2): 251-254
[221] Gan L M, Chieng T H, Chew C H, et al. Microporous polymeric materials from microemul sion polymerization [J]. Langmuir, 1994, 10: 4022
[222] Liu J, Gan L M, Chew C H, et al. Nanostructured polymeric materials from microemulsion polymerization using Poly(ethylene oxide) Macromonomer [J]. Langmuir, 1997, 13(24): 6421-6426
[223] Schmuhl N, Davis E, Cheung H M. Morphology of thermally polymerized microporous polymer materials from methyl methacrylate and 2-hydroxyethyl methacrylate microemulsions [J]. Langmuir, 1998, 14(14): 757-761
[224] Yeoh K W, Chew C H, Gan L M, et al. Micellar polymerization of sodium 11- (N-ethylacrylamido) undecanoate : kinetics and solution properties [J]. J Macromol Sci Chem A,1990, 27(1): 63-85
[225] Chew C H, Li T D, Gan L M, et al. Synthesis and polymerization of a zwitterionic betaine surfactant: Acryloylundecyldimethylammonio acetate [J]. J Macromol Sci Pure Appl Chem A,1995, 32(2): 211-225
[226] Gan LM, Li TD, Chew CH, et al. Microporous polymeric materials from polymerization of zwitterionic microemulsions [J]. Langmuir ,1995, 11(9): 3316–20
[227] Liu J, Chew C H, Gan L M. Synthesis and polymerization of a nonionic surfactant : Poly(ethylene oxide) macromonomer [J]. J Macromol Sci Pure Appl Chem A, 1996, 33(3): 337-352
[228] Liu J, Teo W K, Chew C H, et al. Nanofiltration membranes prepared by direct microemulsion copolymerization using poly(ethylene oxide) macromonomer as a polymerizable surfactant [J]. J Appl Polym Sci, 2000, 77(12): 2785–2794
[229] Bennett D J, Burford R P, DavisT P, et al. Synthesis of porous hydrogel structures by polymerizing the continuous phase of a microemulsion [J]. Polymer International, 1995, 36(3) :219-226
[230] Menger F M, Tsuno T. Synthesis of porous polystyrene with chemically active surfaces [J]. J Am Chem Soc, 1990, 112: 6723-6732
[231] Gupta B, Singh H. Polymerization in microemulsion systems [J]. Polymer-Plastics Technology and Engineering, 1992, 31: 635-658
[232]刘杰,刘少杰,吕峰峰.微乳液体系作为药物载体的研究进展[J].日用化学工业, 2004, 34(2): 100-104
[233]刘玲霞,叶聪.微乳液聚合制备多孔材料的研究[J].安徽化工, 2005(5): 12-14
[234]黎小武,刘建强,姚志钢等.微乳液聚合制备丙烯酸酯类高吸油性树脂工艺条件的探讨[J].化学世界, 2007, (1): 56-59
[235]杨杰,舒武炳,秦卫.微乳液聚合制备多孔高吸油甲基丙烯酸酯类树脂的研究[J].高分子学报, 2010, (7): 910-917
[236] Nakashima T, Kimizuka N. Vesicles in salt: Formation of bilayer membranes from dialkyldi- methylammonium bromides in ether-containing ionic liquids [J]. Chem Lett, 2002, 31: 1018-1019
[237] Hao J C, Song A X, Wang J Z, et al. Self-assembled structure in room-temperature ionic liquids [J]. Chem Eur J, 2005, 11: 3936-3940
[238] Tang J, Li D, Sun CY, et al. Temperature dependant self-assembly of surfactant Brij76 in room temperature ionic liquid [J]. Colloids and surfaces A, 2006, 273(1-3): 24~28
[239]董彬,郑利强.离子液体参与构筑的微乳液:离子液微乳液[J].中国科学:化学, 2010, 40(9): 1266-1275
[240] Qiu Z, Texter J. Ionic liquids in microemulsions [J]. Curr Opin Colloid Interface Sci , 2008, 13: 252-262
[241] GaoH X, Li J C, Han B X, et al. Microemulsions with ionic liquid polar domains [J]. PhysChem Chem Phys, 2004, 6: 2914-2916
[242] Eastoe J, Gold S, Rogers S E, et al. Ionic liquid-in-oil microemulsions [J]. J Am Chem Soc, 2005, 127: 7302-7303
[243] GaoY A, LiN, ZhengLQ, et al. The effectofwateron the microstructure of 1-butyl-3-methylimi- dazolium tet-rafluoroborate/TX-100/benzene ionic liquid microemul-sions [J]. Chem Eur J, 2007(13): 2661-2770
[244] Gao Y A, LiN, Zheng L Q, et a.l. Role of solubilized water in the reverse ionic liquidmicroemulsion of1-butyl-3-methylimi-dazolium tetrafluoroborate/TX-100/benzene [J]. J Phys Chem B, 2007, 111: 2506-2513
[245] Li N, Gao Y A, Zheng L Q, et al. Studies on the mi-cropolarities of[bmim][BF4] /TX-100/toluene ionic liquid microemulsions andtheir behaviors characterized by UV/visible spectroscopy [ J]. Langmuir, 2007, 23: 1091-1097
[246] GaoY A, Wang S Q, Zheng L Q, et al. Microregion detection of ionic liquid microemulsions [J]. J Colloid Interface Sci, 2006, 301: 612-616
[247] GaoY A, Zhang J, Xu H Y, et al. Structural studies of 1-butyl-3-methylimidazolium tetrafluoroborate /TX-100/p-xylene ionic liquid microemulsions [J]. Chemphyschem, 2006(7): 1554-1561
[248] Atkin R, WarrG G. Phase behavior and microstructure ofmicroemulsionswith a room-temperature ionic liquid as the polar phase[ J]. J Phys Chem B, 2007, 111: 9309-9311
[249]郑永军,吾满江·艾力. Tween80/BmimPF6/醇/甲苯体系的相行为[J].物理化学学报, 2008, 24(11): 2143-2148
[250]雷达,范芳,严建芳.甲苯/TX-100 /1-丁基-3-甲基咪唑六氟磷酸盐微乳液的相结构研究[J].华中师范大学学报(自然科学版), 2007, 41(3): 403-405
[251]李娜.离子液体中分子有序组合体的研究[D].济南:山东大学, 2009
[252]戴拓苏.离子液体中两亲分子有序组合体的结构及应用研究[D].扬州:扬州大学, 2009
[253] GaoY A, Li N, Zheng L Q, et al. A cyclic voltammetric technique for the detection ofmicro-regions ofbmim-PF6 / Tween 20 / H2O microemulsions and their performance characterization by UV / Vis spectroscopy [J]. Green Chem, 2006(8): 43-49
[254] GaoY A, Han S B, Han B X, et al. TX-100 / water / 1-butyl-3-methylimidazolium hexafluorophosphate microe-mulsions [J]. Langmuir, 2005, 21: 5681-5684
[255] Cheng S Q, Fu X G, Liu J H, et al. Study of ethyleneglycol / TX-100 / ionic liquid microemulsions [J]. Colloids Surf A, 2007, 302: 211-215
[256] Friberg S E. Evaporation from an ionic liquid emulsion[J]. J Colloid Interface Sci, 2007, 307: 494-499
[257] Friberg S E, Yin Q, PavelF, et al. Solubilization of an ionic liquid, 1-butyl-3-methylimi- dazolium hexafluoro-phosphate, in a surfactant / water system [J]. J Dispers Sci Technol, 2000(2): 185-197
[258]刘丽萍.多相平衡微乳液、模板效应与离子液体调节微乳液曲率研究[D].济南:山东大学, 2009
[259]史传红. H2O/[BMIM]PF6微乳液中酶催化反应[D].济南:山东大学, 2008
[260] Yan F, Texter J. Surfactant ionic liquid-based microe-mulsions for polymerization [J]. Chem Commun, 2006,25: 2696-2698
[261] Yan F, Texter J. Solvent-reversible poration in ionic liquid copolymers [J]. Angew Chem IntEd, 2007, 46: 2440-2443
[262] Qin C K, Chai J L, Chen J F. Studies on the phase be-havior and solubilization of the microemulsion formed by surfactant-like ionic liquidswithε-β-fish-like phase diagram [J].Colloid Polym Sci, 2008, 286: 579-586
[263]秦承宽,咪唑类离子液体在微乳液中的应用及性质研究[D].济南:山东师范大学, 2008
[264]李艳.离子液体型表面活性剂表面吸附及其微乳液的相行为研究[D].济南:山东师范大学, 2010
[1]王潍平,杨锦宗.琥珀酸酯磺酸钠的合成与应用[J].化学粘合,1991, (2): 126-129
[2]葛虹.琥珀酸酯磺酸盐系列表面活性剂的合成与开发[J].表面活性剂工业, 1992, (11): 1-6
[3]常致成.磺基琥珀酸酯盐国内开发生产的技术动态浅析[J].北京日化, 1995, (3): 7-14
[4] Krystyna B, Xavier C,Chantal L. Synthesis and surfactant properties of symmetric and unsymmetric sulfosuccinic diesters,Aerosol-oT homologues [J]. J Chem Soc, Perkin Trans 2, 2001: 2179-2188
[5]李喜敏,张跃军,曲文超.壬基酚聚氧乙烯醚(n)磺基琥珀酸单酯二钠盐系列表面活性剂的合成、结构与性能[J].石油化工, 2001, 30(8): 628-630
[6]张跃军,华平.磺基琥珀酸酯盐类表面活性剂的研究进展[J].江苏化工, 2001, 29(6): 16~26
[7]李喜敏.磺基琥珀酸酯钠盐系列表面活性剂的合成与性能研究[D].南京:南京理工大学, 1998
[8]华平.磺基琥珀酸二己酯钠盐合成工艺和性能研究[D].南京:南京理工大学, 2001
[9]丛川波.琥珀酸二辛酯磺酸钠类乳化剂的合成及其微乳液性质与应用初探[D].青岛:青岛科技大学, 2004
[10] Moreland W T. Triethylamine salts in the preparation of esters from active halogen compounds [J]. J Org Chem, 1956, 21(7): 820-821
[11] Merker R L, Scott M J. The reaction of alkyl halides with carboxylic acids and phends in the presence of tertiary amines [J]. J Org Chem, 1961, 26(12): 5180-5182
[12]山下修,森山登.新颖磺基琥珀酸双酯盐的制备及其含有该成分的反应型表面活性剂组成物[P] .昭58-203960, 1983
[13] Brinchi L, Germani R, Savelli G. Ionic liquids as reaction media for esterification of carboxylate sodium salts with alkyl halides [J]. Tetrahedron Letters, 2003, 44: 2027-2029
[14] Anthony J, O'Lenick J, Wayne C S. Sulfosuccinates [J].Soap/Cosmetics/Chemical Specialties, 1988, (10): 35-40
[15]张金莲,蒋敏海,周镇江.磺基琥珀酸钠的合成与新产品开发[J].化工时刊, 1993, (9): 3-5
[16]马奉奇.温和型表面活性剂一磺基琥珀酸酯[J].辽宁化工, 1991, (6): 15-19
[17]姚志钢,李干佐,胡艾希.双子表面活性剂——二元醇双琥珀酸双酯磺酸钠(GMI-01)的合成与性能研究[J].精细化工, 2003, 20(11): 655-659
[18]姚志钢,李干佐,董凤兰,等. Gemini表面活性剂合成进展[J].化学进展, 2004, 16(3): 349-364
[19]毛培坤.表面活性剂产品工业分析[M].北京:化学工业出版社, 2003: 407-436
[1] Liu S Y, Gonzalez Y I, Kaler E W. Structural fixation of spontaneous vesicler in aqueous mixtures of polymerizable anionic and cationic surfacants [J]. Langmuir, 2003, 19: 10732-10738
[2] Wang Xiang-ying, Zeng Guang-ming, Wang Yi-lin et.al. Salt effect on polymerizable vesicles of allyl dodecyl dimethylammonium bromide and sodium dodecyl sulfonate inaqueous solution [J]. Chinese Journal of Chemistry, 2008, 26(3): 439-444
[3] Regen S L, Czech B, Singh A. Polymerized vesicles [J]. J Am Chem Soc, 1980, 102(21): 6638-6640
[4] Fendler J H. Polymerized surfactant vesicles: Novel membrane mimetic systems [J]. Science, 1984, 223: 888-894
[5] Fendier J H, Tundo P. Polymerized surfactant aggregates-characterization and utilization [J]. Acc Chem Res, 1984, 17(1): 3-8
[6]孙彦,刘敬义,于凯,等.聚合脂质体[J].有机化学, 1994, 14(5): 468-479
[7]王湘英,两亲分子聚合囊泡的合成及其对有机污染物的增溶行为[D].长沙:湖南大学, 2008
[8] Kaler E W, Murthy A K, Rodriguez B E, et al. Spontaneous vesicle formation in aqueous mixtures of single-tailed surfactants [J]. Science, NewSeries, 1989, 245(4924): 1371-1374
[9]于网林表面活性剂分子有序组合体的研究[D].北京:北京大学, 1995: 18
[10]余娜.囊泡的自发形成与其稳定性的研究[D].吉林:吉林大学, 2007: 23
[11] Yukishige K, Hirotaka U, Norio Y, et al. Spontaneous vesicle formation from aqueous solutions of didodecyldimethylammonium bromide and sodium dodecyl sulfate mixtures [J], Langmuir, 1995, 11(7): 2380-2384
[12] Winterhalter M, Helfrich W. Bending elasticity of electrically charged bilayers:coupled monolayers, neutral surfaces, and balancing stresses[J]. Z Phys Chem, 1992, 96(1): 327-330
[13] Nakashima T, Shigematsu M, Ishibashi Y, et al. Stopped-flow kinetic study on aggregation of dilauroylphosphatidic acid vesicles induced by divalent cations [J]. J Coll Interface Sci, 1990, 136(2): 447-454
[14] Carmona-Ribeiro A M, Yoshide L S,Chaimovich H. Salt effects on the stability of dioctadecyldi- methylammonium chloride and sodium dihexadecyl phosphate vesicles [J]. J Phys Chem, 1985, 89(13): 2928-2933
[15] Ohki S, Duzgunes N, Leonards k.. Phospholipid vesicle aggregation: effect of monovalent and divalent ion [J]. Biochem, 1982, 21(9): 2127-2133
[16] Inoue T, Minami H, Shimozawa R, et al. Stability of DLPA/DLPC mixed vesicles against divalent cation-induced aggregation: Importance of the hydration force [J]. J Coll Interface Sci, 1992, 152(2): 493-506
[17] Minami H, Inoue T, Shimozawa R.. Aggregation kinetics of dimyristoyl- phosphatidylglycerol vesicles induced by divalent cations [J]. J Coll Interface Sci, 1993, 158(2): 460-465
[18] Zeng J, Smish K E, Chong P L G. Effects of alcohol-induced lipid int-erdigitation on proton permeability in L-alpha-dipalmitoylphatidylcholine vesicles [J]. Biophys J, 1993, 65: 1404-1414
[19] Huang J B, Zhu B Y, Zhang Z Y. Vesicle formation of a 1:1 catanionic surfactant mixture in ethanol solution [J]. Langmuir, 1997, 13: 5759-5761
[20]孙丹.囊泡的稳定性与其在制备聚合物中空微球中的应用研究[D].吉林:吉林大学, 2008:38
[21] Ray A. Solvophobic Interactions and micelle formation in structure forming nonaqueous solvents [J]. Nature, 1971, 231: 313-315
[22] Huang J B, Zhu B Y, Zhao G X, et al. Vesicle formation of a 1:1 catanionic surfactant mixture in ethanol solution [J]. Langmuir, 1997, 13(21): 5759-5761
[23]余娜.囊泡的自发形成与其稳定性的研究[D].吉林:吉林大学, 2007: 39
[24]黄建滨,赵国玺.正负离子表面活性剂混合溶液中囊泡的稳定性[J].北京大学学报(自然科学版), 1999, 35(2):144-150
[1]郝永梅.非离子表面活性剂囊泡作为药物载体的研究[D].北京:北京大学, 2002
[2]李载常.脂质体研究进展[J].国外医学生理、病理科学与临床分册, 1999, 19(15): 3-7
[3] Rahman Y E, Cerny E A, Tollaksen S L, et al. Liposome-encapsulated actinomycin D: potential in cancer chemotherapy [J]. Proc Soc Exp Biol Med, 1974, 146(4): 1173-1176
[4] Ryman B E. The use of lipsomes as carriers of drugs and other cell modifying molecules [A]. Proc Int Congr Pharmacol 6th(Publ 1976),1975
[5] Gregoriadis G. The carrier potential of liposomes in biology and medicine [J]. New Engl J Med. 1976, 295: 704-710
[6] Lawrence M J. Surfactant systems:Microemulsions and vesicles as vehnicles for drug delivery[J]. Eur J Drug Metab Pharmacokinet, 1994, 3:257-263
[7]蔡明志,王昆.载药脂质体的物理化学稳定性的研究进展[J].国外药物科学—医药部分, 2005, 32(6): 404-407
[8]姜树红,戈延茹,汪珠燕.非离子表面活性剂囊泡的研究进展[J].中国现代药物应用, 2007, 1(11): 98-101
[9]邓英杰主编.脂质体技术[M].北京:人民卫生出版社, 2007
[10]王思玲,苏德森主编.胶体分散药物制剂[M].北京:人民卫生出版社, 2006
[11] Torchilin V P, Weissig V,脂质体[M].邓章辉,徐晖主译.北京:化学工业出版社, 2007
[12]黄义昆.脂质体作为药物载体研究进展[J].中国药师, 2005, 8(7): 549-550
[13]李唐棣,郝丽梅.脂质体包封率的研究进展[J].国外药物科学—医药部分, 2006, 33(3): 224-227
[14] Regen S L. Polymerized phosphatidylcholine vesicles as drug carriers [J]. Ann N Y Acad Sci, 1985, 446: 296-307
[15] Okada J, Cohen S, Langer R S. Oral Delvery of vaccines using polymerized liposomes [P]. US: 5,762,904, 1998
[16] Okada J, Cohen S, Langer R S. In vitro evaluation of polymerized liposomes as an oral drug delivery system [J]. Pharm Res, 1995, 12(4): 576-582
[17] Guo Caixin, Liu Shaoqin, Jiang Chang, et al. A Promising drug controlled-release system based on diacetylene/phospholipid polymerized vesicles [J]. Langmuir, 2009, 25(22): 13114-13119
[18]安娅,胡长刚,张笑一. PTA/AOT自发形成囊泡作为药物载体的缓释性研究[J].贵州师范大学学报(自然科学版), 2005, 23(3): 105-107
[19]邓英杰主编,脂质体技术[M].北京:人民卫生出版社, 2007: 128
[20]王雪超.盐酸小檗碱囊泡的制备及体内外研究[D].河北医科大学, 2009: 54
[21]陈文君,曾宪诚等.囊泡的自发形成—两类表面活性剂复配[J].科学通报, 2003, (6): 2-8
[1]胡玉山,张政朴,何炳林.高吸油性树脂[J].离子交换与吸附, 1999, 15(4): 378-384
[2] Dow Chem Co Ltd. Oil-absorbing polymer [P]. JP:昭45-27081, 1970
[3] Nippon Shokubai Co Ltd.膨润性吸油剂的制造方法[P]. JP:平05-32708, 1993
[4]李培勋,于波,卫秀成,等.吸油树脂的研究进展[J].材料工程, 2002, (10): 39-42
[5]魏徵,王源升,余红伟.高吸油性树脂的研究进展[J].材料开发与应用, 2010, 25(6): 77-80
[6]柳颖,徐明,张洪林等.高吸油树脂的研究及应用进展[J].化学与生物工程, 2009, 26(9): 7-10
[7]张高奇,周美华,梁伯润.高吸油树脂的研究与发展趋势[J].化工新型材料, 2002, 30(1): 29-31
[8]张文林,唐建军,邵拥军,等.高吸油树脂的开发与应用前景[J].天津理工学院学报, 2002, 18(2): 33-35
[9]王勇,张玉英.高吸收树脂的研究进展[J].中国塑料, 2001, 15(10): 14-17
[10]费晓峰,张季爽.高吸油树脂的研究进展[J].现代化工, 1998, (1): 13-15
[11]徐相凌,殷亚东,葛学武,等.微乳液聚合研究进展[J].高等学校化学学报, 1999, 20: 478-485
[12]高静,李晓,张卫英.双连续相微乳液聚合特征与应用[J].合成橡胶工业, 2003, (5): 319-323
[13] Gan L M, Liu J, Poon L P, et al. Microporous polymeric composites from bicontinuous microemulsion polymerization using a polymerizable nonionic surfactant [J]. Polymer, 1997, 38(21): 5339-5435
[14] Gan L M, Chieng T H, Chew C H, et al. Microporous polymeric materials from microemulsion polymerization [J]. Langmuir, 1994, 10: 4022-4027
[15] Liu J, Gan L M, Chew C H, et al. Nanostructured polymeric materials from microemulsion polymerization using poly(ethylene oxide) macromonomer [J]. Langmuir, 1997, 13(24): 6421-6426
[16] Chew C H, Li T D, Gan L H, et al. Bicontinuous-Nanostructured polymeric materials from microemulsion polymerization [J]. Langmuir, 1998, 14(21): 6068-6076
[17]杨杰,舒武炳,秦卫.微乳液聚合制备多孔高吸油甲基丙烯酸酯类树脂的研究[J].高分子学报, 2010, (7): 910-917
[18]杨俊华.高吸油性树脂[J].石油化工, 1991, (4): 39-43
[19]薛美玲,张积树,于永良等.微乳液变形及W/O型导电机理的研究[J].青岛化工学院学报, 1998, 19(1): 21-25
[20]郝京诚,郑立强,李干佐等.阳离子表面活性剂相图和微乳液结构的研究[J].山东大学学报(自然科学版), 1996, 31(2):196-200
[21]朱秀林.丙烯酸甲酯和甲基丙烯酸酯共聚及性能研究[J].高分子材料科学与工程, 1995, 11(1): 19-23
[22] Palani Raj W R, Sasthav M, Cheung H M. Microcellular polymeric materials from microemulsion control of microstructure and morphology [J]. Journal of Applied Polymer Science, 1993, 47: 499-511
[1]高静.微乳液聚合制备透明多孔MMA-BA共聚物[D].福州:福州大学, 2003
[2] Yue D M,Yu J, Zhang Q, et al. Preparation of nano-porous materials(I) by polymerization of amphiphile self-assemblies [J]. Chem Res Chinese U, 2003, 19(1): 112-119
[3] Hentze H P, Antonietti M. Template synthesis of porous organic polymers [J]. Current Opinion in Solid State and Materials Science, 2001, 5: 343–353
[4] Gan L M, Chew C H. Polymerization in the transparent water-in-oil solutions I: Methyl methacrylate and the copolymerizable cosurfactant [J]. J Dispersion Sci Technol, 1983, 4(3): 291-312
[5] Palani Raj W R, Sasthav M, Cheung H M. Synthesis of porous polymeric membranes by polymerization of micro-emulsions [J]. Polymer, 1993, 34(15): 3305-3312
[6] Liu J, Gan L M, Chew C H, et al. Nanostructured polymeric materials from microemulsion polymerization using poly(ethylene oxide) macromonomer [J]. Langmuir, 1997, 13(24): 6421-6426
[7] Chew C H, Li T D, Gan L H, et al. Bicontinuous-Nanostructured Polymeric Materials from Microemulsion Polymerization [J], Langmuir, 1998, 14(21): 6068-6076
[8] Gan L M, Liu J, Poon L P, et al. Microporous polymeric composites from bicontinuous microemulsion polymerization using a polymerizable nonionic surfactant [J]. Polymer, 1997, 38(21): 5339-5435
[9] Welton T. Room-Temperature ionic liquids solvents for synthesis and catalysis[J]. Chem Rev, 1999, 99: 2071-2084
[10]李汝雄.绿色溶剂-离子液体的合成与应用[M].北京:化学工业出版社, 2004: 3-9
[11]张建玲,韩布兴,程四清.离子液体相关微乳液体系[R].北京:中国科学院化学研究所, 2007
[12]张国栋,陈晓,靖波.室温离子液体中的有序分子组合体[J].化学进展, 2006, 18: 1085-1091
[13] Friberg S E. Evaporation from an ionic liquid emulsion[J]. J Colloid Interface Sci, 2007, 307: 494-499
[14] Eastoe J, Gold S, Rogers S E, et al. Ionic liquid-in-oil microemulsions [J]. J Am Chem Soc, 2005, 127: 7302-7303
[15] Kubisa P. Application of ionic liquids as solvents for polymerization processes[J]. Prog Polym Sci, 2004, 29(1): 3-12
[16]陈珍珍.离子液体微乳液中原子转移自由基聚合研究[D].苏州:苏州大学, 2010
[17] Yu Shaomei, Yan Feng , Zhang Xingwang, et al. Polymerization of ionic liquid-based microemulsions: A versatile method for the synthesis of polymer electrolytes[J]. Macromolecules, 2008, 41: 3389-3392
[18]俞绍玫.基于离子液体微乳液的研究及其功能聚合物材料的研究[D].苏州:苏州大学, 2009
[19] Yan Feng, Yu Shaomei, Zhang Xingwang, et al. Enhanced proton conduction in polymer electrolyte membranes as synthesized by polymerization of protic ionic liquid-based microemulsions[J]. Chem Mater, 2009, 21: 1480–1484
[20] Yan F,Texter J. Surfactant ionic liquid-based microemulsions for polymerization[J]. Chem.Commun, 2006, 25: 2696-2698
[21] Yan F, Texter J. Solvent-reversible poration in ionic liquid copolymers [J]. Angew Chem Int Ed, 2007, 46: 2440-2443g
[22]周舟,何德良,李雪玲等.聚苯胺在离子液体/水体系中的微乳液法合成[J].高分子学报, 2007, (8): 757-760
[23]周舟.室温离子液体中纳米导电聚合物材料的制备[D].长沙:湖南大学, 2009
[24]郭艳妮.离子液体型导电聚合物纳米材料的制备与表征[D].长沙:湖南大学, 2010
[25]钟建芳.离子液体中羟基新戊醛的电化学行为和导电聚苯胺的制备[D].长沙:湖南大学, 2008
[26] Chieng T H, Gan L M, Chew C H, et al. Formation of microporous polymeric materials by microemulsion polymerization of methyl methacrylate and 2-hydroxyethyl methacrylate [J]. J Appl Polym Sci, 1996, 60(10): 1561-1564
[27] Gan L M, Chew C H. Microporous polymer composites from microemulsion polymerization [J]. Colloids and Surfaces A, 1997, 123-124: 681-693
[28] Burban J H, Mengtrao He, Cussler E L. Organic microporous materials made by bicontinuous microemulsion polymerization [J]. AIChE Journal, 1995, 41(4): 907-914
[29] Palani Raj W R, Sasthav M, Cheung H M. Microcellular polymeric materials from microemulsion control of microstructure and morphology [J]. J Appl Polym Sci, 1993, 47: 499-511
[2]朱步瑶,赵振国.界面化学基础[M].北京:化学工业出版社, 1996
[3]赵国玺.表面活性剂物理化学[M]. 2版.北京:北京大学出版社, 1991
[4]赵国玺,朱步瑶.表面活性剂作用原理[M].北京:中国轻工业出版社, 2003
[5] Hoffmann M M, Heitz M P, Carr J B, et al. Surfactants in green solvent systems - Current and future research directions [J]. J Dispersion Sci Technol, 2003, 24(2): 155-171
[6]韩峰,清洁介质中表面活性剂分子聚集体的构建[D].武汉:武汉工业学院, 2008
[7]张国栋,陈晓,靖波.室温离子液体中的有序分子组合体[J].化学进展, 2006, 18: 1085-1091
[8] Hao J C, Zemb T. Self-assembled structures and chemical reactions in room-temperature ionic liquids [J]. Curr Opin Colloid Interface Sci, 2007, 12: 129-137
[9]高艳安.在绿色溶剂中超分子结构研究—微乳液,环糊精与离子液包容相互作用[D].济南:山东大学, 2005
[10] Fendler J H. Polymerized surfactant vesicles: novel membrane mimetic systems [J]. Science, 1984, 223: 888-894
[11] Gros L, Ringsdorf H, Schupp H. Polymeric antitumor agents on a molecular and on a cellular level [J] Angew Chem, Int Ed Engl. 1981, 20: 305-325
[12] Paleos C M. Polymerization in organized systems [J]. Chem Soc Rev.1985, 45:45-66.
[13] Bader H, Dorn K, Hupfer B, et al. Polymeric monolayers and liposomes as models for biomembranes -How to bridge the gap between polymer science and membrane biology [J]. Adv Polym Sci, 1985, 64: 1-62
[14] Regen S L. Polymerized liposomes [M]. New York, Marcel Dekker, 1987: 73-108
[15] Ringsdorf H, Schlarb B, Venzmer J. Molecular architecture and function of polymeric oriented systems: models for the study of organization, surface recognition, and dynamics of biomembranes [J]. Angew Chem, Int Ed Engl, 1988, 27(1): 113-158
[16] O’Brien D F, Ramaswami V. Polymerized vesicles [J]. Encycl Polym Sci Eng, 1989, 17: 108-135
[17] Singh A, Schnur J M.. Polymerizable phospholipids [M]. New York, Marcel Dekker,1993: 233-291
[18] Singh A, Markowitz M, Chow G M. Materials fabrication via polymerizable self-organized membranes: an overview [J]. NanoStructured Materials, 1995, 5(2): 141-153
[19] O’Brien D F, Armitage B, Benedicto A, et al. Polymerization of preformed self-organized assemblies[J]. Acc Chem Res, 1998, 31(12): 861-868
[20] Miller S A, Ding J H, Gin D L. Nanostructured materials based on polymerizable amphiphiles[J]. Curr Opin Colloid Interface Sci, 1999, 4(5):338-347
[21] Keisuke Tajima, Takuzo Aida. Controlled polymerizations with constrained geometries [J]. Chem Commum, 2000, 2399-2412
[22] Hubert D H W, Jung M, German A L. Vesicles templating [J]. Adv Mater, 2000, 12: 1291-1294
[23] Mueller A, O’Brien D F. Supramolecular materials via polymerization of mesophases of hydrated amphiphiles [J]. Chem Rev, 2002, 102(3): 727-757
[24] Hentze H P, Kaler E W. Polymerization of and within self-organized media [J]. Curr Opin Colloid Interface Sci, 2003, 8: 164-178
[25] Summers M, Eastoe J. Applications of polymerizable surfactants [J]. Adv Colloid Interface Sci, 2003, 100-102: 137-152
[26] Yan Feng, John Texter. polymerization of and in mesophases[J]. Adv Colloid Interface Sci, 2006, 128-130: 27-35
[27] Mattew P C, Timothy E L. Biomimetic design and performance of polymerizable lipids [J]. Acc Chem Res, 2009, 42(8):1016-1025
[28] Merrigan T L,Bates E D, Dorman S C. New fluorous ionic liquids function as surfactants in conventional room-temperature ionic liquids [J]. Chem Commun, 2000, 2051-2052
[29] Kimizuka N, Nakashima T. Spontaneous self-assembly of glycolipid bilayer membranes in sugar– philic ionic liquids and formation of ionogels [J]. Langmuir, 2001, 17(22): 6759-6761
[30] Hoefling T A, Enick R M E, Beckman E J. Microemulsions in near-critical and supercritical carbon dioxide [J]. J Phys Chem, 1991, 95: 7127-7129
[31] Zemb T, Duboism, Deme B, et a.l. Self-assembly of flatnanodiscs in salt-free catanionic surfactant solutions [J]. Science, 1999, 283: 816-819
[32] Duboism, Deme B, Gulikkrzywickit, et al. Self-assembly of regular hollow icosahedra in salt-free catanionic solutions [J]. Nature, 2001, 411: 672-675
[33]姜文清,郝京诚.水相和特殊介质中有序聚集体的结构、性质和应用(1) [J].日用化学工业, 2008, 38(4): 257-266
[34].Israelachvili J N, Mitchell D J, Ninham B W. Theory of selfassembly of hydrocarbon amphiphiles into micelles and bilayers [J]. J Chem Soc, Faraday TransⅡ, 1976, 72: 1525-1568
[35] Winterhalter M, Helfrich W. Bending elasticity of electrically charged bilayers: coupled monolayers, neutral surfaces, and balancing stresses [J]. J Phys Chem, 1992, 96(1): 327-330
[36] Leng J, Egelhaaf S U, Cates M E. Kinetics of the micelle-to-vesicle transition: Aqueous lecithin- bile salt mixtures [J]. Biophysical Journal, 2003, 85: 1624–1646
[37] Rusanov A I. Thermodynamics of vesicles [J]. Colloids and Surfaces A, 1993,76: 7-13
[38] Leermakers F A M, Scheutjens J M H M. Statistical thermodynamics of association colloids : lipid vesicles [J]. J Phys Chem, 1989, 93(21):7417-7426
[39] Safran S A, Pincus P, Andelman D. Theory of spontaneous vesicle formation in surfactant mixtures [J]. Science, 1990, 248(4953): 354-356
[40] Freedman H H, Mason J P, Medalia A I. Polysoaps:ⅡThe preparation of vinyl soaps [J]. J Org Chem, 1958, 23(1): 76-82
[41] Holmberg K. Polymerizable surfactants [J]. Prog Org Coat, 1992, 20(3-4): 325-337
[42] Digioia F A, Nelson R E. Freeze -Thaw studies of latex paint polymers[J]. Ind Eng Chem, 1953, 45(4): 745-748
[43] Kronberg B, Kuortti J, Stenius P. Competitive and cooperative adsorption of polymers and surfactants on kaolinite surfaces [J]. Colloids Surf A, 1986, 18(2-4): 411-425
[44] Hulden M, Sjoblom E. Adsorption of some common surfactants and polymers on TiO2-pigments [J]. Prog Colloid Polym Sci, 1990, 82: 28–37
[45] Evanson K W, Urban M W. Surface and interfacial FTIR spectroscopic studies of latexes. I. Surfactant– copolymer interactions [J]. J Appl Polym Sci, 1991, 42(8): 2287–2296
[46] Evanson K W, Thorstenson T A, Urban M W. Surface and interfacial FTIR spectroscopic studies of latexes II Surfactant–copolymer compatibility and mobility of surfactants [J]. J Appl Polym Sci, 1991, 42(8): 2297–2307
[47] Guyot A, Tauer K. Reactive surfactants in emulsion polymerization [J]. Adv Polym Sci, 1994, 111: 43–65
[48] Guyot A. Advances in reactive surfactants [J]. Adv Colloid Interface Sci, 2004, 108-109: 3-22
[49] Soula O, Guyot A, Williams N, et al. Styrenic surfmer in emulsion copolymerization ofacrylic monomers II Copolymerization and film properties [J]. J Polym Sci, Part A: Polym Chem, 1999, 37 (22): 4205–4217
[50] Sindt O, Gauthier C, Hamaide T, et al. Reactive surfactants in heterophase polymerization. XVI. Emulsion copolymerization of styrene–butyl acrylate–acrylic acid in the presence of simple maleate reactive surfactants [J]. J Appl Polym Sci , 2000, 77(12): 2768–2776
[51] UnzuéM J, Schoonbrood H A S, Asua J M, et al. Reactive surfactants in heterophase polymerization VI Synthesis and screening of polymerizable surfactants (surfmers) with varying reactivity in high solids styrene-butyl acrylate-acrylic acid emulsion polymerization [J]. J Appl Polym.Sci, 1997, 66(9): 1803–1819
[52] Aramendia E, Mallégol J, Jeynes C, et al. Distribution of surfactants near acrylic latex film surfaces: A comparison of conventional and reactive surfactants (Surfmers) [J]. Langmuir, 2003, 19(8): 3212-3221
[53] Yokota K, Ichihara A, Shinike H. Surfactant [P]. US: 5 324 862, 1994
[54] Aramendia E, Barandiaran M J, Grade J, et al. Improving water sensitivity in acrylic films using surfmers [J]. Langmuir, 2005, 21(4): 1428-1435
[55] Abele S, Gauthier C, Graillat C, et al. Films from styrene–butyl acrylate lattices using maleic or succinic surfactants: mechanical properties, water rebound and grafting of the surfactants [J]. Polymer, 2000, 41(3): 1147–1155
[56] Amalvy J I, Unzue M J, Schoonbrood H A S, et al. Reactive surfactants in heterophase polymerization: Colloidal properties, film-water absorption, and surfactant exudation [J]. J Polym Sci, Part A: Polym. Chem, 2002, 40(17): 2994–3000
[57] Greene B W, Sheetz D P, Filer T D. In situ polymerization of surface-active agents on latex particles I. Preparation and characterization of styrene/butadiene latexes [J]. J Colloid Interface Sci, 1970, 32(1): 90–95
[58] Greene B W, Sheetz D P. In situ polymerization of surface-active agents on latex particles II. The mechanical stability of styrene/butadiene latexes [J]. J Colloid Interface Sci, 1970, 32(1): 96–105
[59] Guyot A. Recent progress in reactive surfactants in emulsion polymerisation [A]. Macromol Symp, 2002, 179:105-132
[60] Asua J M, Schoonbrood H A S. Reactive surfactants in heterophase polymerization[J]. Acta Polym, 1998, 49(12): 671-686
[61]朱明月,乔卫红,毕晨光等.乳液聚合中的可聚合乳化剂研究进展[J].化工进展,2006, 25(5): 490-494
[62]熊娉婷,鲁德平,黄宏志.可聚合表面活性剂的研究进展[J].高分子通报, 2006,(8): 14-20
[63] Stoffer J O, Bone T. Polymerization in water in oil microemulsion systems containing methyl methacrylate [J], J Dispersion Sci Technol, 1980, 1: 393-398
[64] Stoffer J O, Bone T. Polymerization in water-in-oil microemulsion systems I [J]. J Polym Sci Polym Chem Ed, 1980, 18(8): 2641-2648
[65] Atik S S, Thomas K J. Polymerized microemulsions[J]. J Am Chem Soc, 1981, 103(14): 4279-4280
[66] Atik S S, Thomas K J. Photochemistry in polymerized microemulsion systems[J]. J Am Chem Soc,1982, 104(22): 5868-5874
[67] Gan L M, Chew C H. Polymerization in the transparent water-in-oil solutions I: Methyl methacrylate and the copolymerizable cosurfactant [J]. J Dispersion Sci Technol, 1983, 4(3): 291-312
[68] Gan L M, Li T D, Chew C H, et al. Porous polymeric materials from cationic microemulsions [J]. Journal of Macromolecular Science, Part A, 1995, 32(5): 969-980
[69] Gan L M, Li T D, Chew C H, et al. Preparation of ultrafiltration membranes by direct microemulsion polymerization using polymerizable surfactants [J]. Langmuir, 1996, 12(24): 5863-5868
[70] Gan L M, Chieng t H, Chew C H, et al. Microstructural control of porous polymeric materials via a microemulsion pathway using mixed nonpolymerizable and polymerizable anionic surfactants [J]. Langmuir, 1996, 12(2): 319-324
[71] Chew C H, Li T D, Gan L H, et al. Bicontinuous-nanostructured polymeric materials from microemulsion polymerization [J]. Langmuir, 1998, 14(21): 6068-6076
[72] Xu W, Siow K S, Gao Z, et al. Microporous polymeric composite electrolytes from microemulsion polymerization [J]. Langmuir, 1999, 15(14): 4812-4819
[73] Ong C L, Gan L M, Ong C K, et al. Unusual ionic behavior in microemulsion- polymerized membranes [J]. J Phys Chem B, 1999, 103(36): 7573-7576
[74] Chow P Y, Chew C H, Ong C L, et al. Ion-containing membranes from microemulsion polymerization [J]. Langmuir, 1999, 15(9): 3202-3205
[75] Fendier J H, Tundo P. Polymerized surfactant aggregates-characterization and utilization[J]. Acc Chem Res, 1984, 17(1): 3-8
[76]张洪涛,任天斌.可聚合乳化剂的种类及乳液聚合[J].粘接, 1999, (2): 26-28; 1999,(3): 33-36
[77]彭顺金,张贵军,方华,等.反应性乳化剂及其乳液聚合[J].涂料工业, 1999, (5): 36-39
[78]任天斌,张洪涛.可聚合表面活性剂的类型及应用[J] .日用化学工业, 2000, 30(3): 25-28
[79] Varuni Subramaniam. Preparation and characterization of novel lipid and proteolipid membranes from polymerizable lipids [D]. The University of Arizona, 2007: 53
[80]孙彦,刘敬义,于凯,等.聚合脂质体[J].有机化学, 1994, 14(5): 468-479
[81]于网林,赵国玺.囊泡的形成与两亲分子结构[J].化学通报, 1996, 6: 21-25
[82] Fendler J H. Membrane mimetic chemistry(膜模拟化学)[M].程虎民,高月英译,北京:科学出版社, 1991
[83] Schulman J H, Stoeckenius W, Prince L M. Mechanism of formation and structure of microemulsions by electron microscopy [J]. J Phy Chem, 1959, 63 (10): 1677-1680
[84] Bangham A D, Standdish M M, Watkins J. Difusion of univalent ions across the lamellae of swollen phospholipids [J]. J Mol Biol, 1965, 13: 238-242
[85] Kunitake T, Okahata Y A. Totally synthetic bilayer membrane [J]. J Am Chem Soc. 1977, 79: 3860-3861
[86] Talmon Y, Evans D F, Ninham B W. Spontaneous vesicles formed from hydroxide surfactants: evidence from electron microscopy [J]. Science, Newseries, 1983, 221(4615): 1047-1048
[87] Brady J E, Evans D F, Kachar B, et al. Spontaneous vesicles [J]. J Am Chem Soc, 1984, 106(15): 4279-4280
[88] Lin Z, He M, Scriven L E, et al. Vesicle formation in electrolyte solutions of a new cationic siloxane surfactant [J]. J Phys Chem, 1993, 97(14): 3571-3578
[89] Kaler E W, Murthy A K, Rodriguez B E, et al. Spontaneous vesicle formation in aqueous mixtures of single-tailed surfactants [J]. Science, NewSeries, 1989, 245(4924): 1371 - 1374
[90] Herrington K L, Kaler E W. Phase behavior of aqueous mixtures of dodecyl- trimethyl ammonium bromide(DTAB) and sodium dodecyl sulfate(SDS) [J]. J Phys Chem, 1993, 97: 13792-13802
[91] Kaler E W, Herrington K L, Murthy A K. Phase behavior and structures of mixtures of and cationic surfactants [J]. J Phys Chem, 1992, 96: 6698-6707
[92] Yuet P K, Blankschtein D. Effect of surfactant tail-length asymetry on the formation ofmixed surfactant vesicles [J]. Langmuir, 1996, 12:3819-3827
[93] Lasic D D, Joannic R, Keller B C, et al. Spontaneous vesiculation [J]. Adv in Coll Interf Sci, 2001, 89: 337-349
[94] Tondre C, Caillet C. Properties of the amphiphilic films in mixed cationic/anionic vesicles: a comprehensive view from a literature analysis [J]. Adv in Coll Interf Sci, 2001, 93: 115-134
[95] Marques E F, Regev O, Khan A, et al. Vesicle formation and general phase behavior in the catanionic mixture SDS-DDAB-water,the cationic-rich side [J]. J Phys Chem B, 1999, 103(39): 8353-8363
[96] Hofland H E J, Bouwstra J A, Gooris G S, et al. Nonionic surfactant vesicles:A study of vesicle formation,characterization,and stability [J]. J Coll Interf Sci, 1993, 161: 366-376
[97]陈文君,翟利民,李干佐,等.囊泡的自发形成-两类表面活性剂复配[J].科学通报, 2003, 6(48): 562-566
[98] Zhai L M, Li G Z, Sun Z W. Spontaneous vesicle formation in aqueous solution of zwitterionic and anionic surfactant mixture [J]. Colloids and Surfaces A, 2001, 190: 275-283
[99] Bergmerier M, Hoffmann H, Witte F, et al. Vesicles from single-chain hydrocarbon surfactants and perfluoro cosurfactants [J]. J Colloid Interface Sci, 1998, 203(1): 1-15
[100] Hao J C, Hoffmann H. Self-assembled structures in excess and salt-free catanionic surfactant solutions [J]. Curr Opin Colloid Inter Sci, 2004, 9: 279-293
[101] Wang J Z, Song A X, Jia X F, et al. Two routes to vesicle formation:Metal-ligand complexation and ionic interactions [J]. J Phys Chem B, 2005, 109(22): 11126-11134
[102] Hargreaves W R, Deamer D W. Liposomes from ionic, Single-chain amphiphiles [J]. Biochemistry, 1978, 17(18): 3759-3768
[103]赵国玺,黄建滨.表面活性剂混合物水溶液中的囊泡形成[J].物理化学学报, 1992, 8(5): 583-585
[104] Zhao G X, Yu W L. Vesicles from mixed sodium 10-Undecenoate- Decyltrimeth- ylammonium Bromide solutions [J]. J Coll Interface Sci, 1995, 173: 159-164
[105] Jung H T, Coldren B, Zasadzinski J A, et al. The origins of stability of spontaneous vesicles [A]. Proceedings of the National Academy of Sciences of the United States of America, 2001, 98(4): 1353-1357
[106] Liu S Y, Gonzalez Y I, Kaler E W. Structural fixation of spontaneous vesicler in aqueous mixtures of polymerizable anionic and cationic surfacants [J]. Langmuir, 2003,19: 10732-10738
[107] Wang X Y, Zeng GM, Wang Y L, et al. Salt effect on polymerizable vesicles of allyl dodecyl dimethylammonium bromide and sodium dodecyl sulfonate in aqueous solution [J]. Chinese Journal of Chemistry, 2008, 26: 439-444
[108] Hotz J, Meier W. Vesicle-Templated polymer hollow spheres [J]. Langmuir, 1998, 14(5): 1031-1036
[109] Kurja J, Nolte R J M, Maxwell I A, et al. Free radical polymerization of styrene in dioctadecyl dimethylammonium bromide vesicles [J]. Polymer, 1993, 34: 2045-2049
[110] Jung M, Hubert D H W, Bomans P H H, et al. New Vesicle-Polymer hybrids:The parachute architecture [J]. Langmuir, 1997, 13(26): 6877
[111] Poulain N, Nakache E, Pina A, et al. Nanoparticles from vesicle polymerization: characterization and kinetic study [J]. J Polym Sci Part A:Polym Chem, 1996, 34(5): 729-737
[112] Morgan J D, Johnson C A, Kaler E W. Polymerization of equilibrium vesicles [J]. Langmuir, 1997, 13(24): 6447-6451
[113] McKelvey C A, Kaler E W, Zasadzinski J A, et al. Templating hollow polymeric spheres from catanionic equilibrium vesicles:Synthesis and characterization [J]. Langmuir, 2000, 16(22): 8285-8290
[114] Krafft M P, Schieldknecht L, Marie P, et al. Fluorinated vesicles allow intrabilayer polymerization of a hydrophobic monomer,yielding polymerized microcapsules [J]. Langmuir, 2001, 17(9): 2872-2877
[115] Song L Y, Ge X W, Wang M Z, et al. Anionic/nonionic mixed surfactants templates preparation of hollow polymer spheres via emulsion polymerization [J]. J Polym Sci Part A:Polym Chem, 2006, 44(8): 2533-2541
[116]余娜,孙丹,韩兆让. CTAB/SDBS囊泡的自发形成与聚合[J].化学学报, 2008, 66(3): 315-320
[117] Lawrence M J. Surfactant systems: Microemulsions and vesicles as vehicles for drug delivery [J]. Eur J Drug Metab Pharmacokinet, 1994, 19(3): 257-269
[118] Discher D E, Eisenberg A. Polymer vesicles [J]. Science, 2002, 297: 967-973
[119] Liu S C, O'Brien D F. Cross-linking polymerization in two-dimensional assemblies: Effect of the reactive group site [J]. Macromolecules, 1999, 32(17): 5519-5524
[120] Neumann R, Ringsdorf H. Peptide liposomes from amphiphilic Amino-Acids [J]. J Am Chem Soc, 1986, 108(3): 487-490
[121] Neumann R. Preparation and characterization of long-chain Amino-Acid and peptidevesicle membranes [J]. Biochimica Et Biophysica Acta, 1987, 898(3): 338-348
[122] Marques E F. Size and Stability of Catanionic vesicles:Effects of formation path, sonication, and aging [J]. Langmuir, 2000, 16: 4798-4807
[123] Walker S A, Zasadzinski J A. Electrostatic control of spontaneous vesicle aggregation [J]. Langmuir, 1997, 13: 5076-5081
[124] Sun S T, Day E P, Ho J T. Temperature dependence of calcium-induced fusion of sonicated phosphatidylserine vesicles[A]. Proc Natl Acad Sci USA,1978, 75(9): 4325-4328
[125] Sun S T, Hsang C C, Day E P,et al. Fusion of phosphatidylserine and mixed phosphatidylserine- phosphatidylcholine vesicles: Dependence on calcium concentration and temperature [J]. Biochimica et Biophysica Acta (BBA) - Biomembranes, 1979, 557(1): 45-52
[126]韩峰,付宏兰,何潇,等.正负离子表面活性剂混合体系中高稳定性囊泡的形成[J].化学学报, 2003, 61(9): 1399-1404
[127]韩秀梅.氟碳型表面活性剂的合成及囊泡的稳定性、包覆性能的研究[D].东北师范大学, 2001
[128]孙丹.囊泡的稳定性与其在制备聚合物中空微球中的应用研究[D].吉林:吉林大学, 2008
[129]余娜.囊泡的自发形成与其稳定性的研究[D].吉林:吉林大学, 2007
[130]于网林表面活性剂分子有序组合体的研究[D].北京:北京大学, 1995
[131]黄建滨,赵国玺.正负离子表面活性剂混合溶液中囊泡的稳定性[J].北京大学学报(自然科学版), 1999, 35(2): 144-150
[132]尹海清.阴阳离子表面活性剂混合体系中有序组合体的调控[D].北京:北京大学, 2006
[133]周文婷,徐晓明,蓝琴,等.囊泡形成和破坏的动力学[J].化学学报, 2007, 65(20): 2279-2284
[134] Regen S L, Czech B, Singh A. Polymerized vesicles [J]. J Am Chem Soc, 1980, 102(21): 6638-6640
[135] Hub H H, Hupfer B, Koch H, et al. Polyreaction in ordered systems 20: polymerizable phospholipid analogs-new stable biomembrane and cell models [J]. Angew Chem Int Edit, 1980, 19(11): 938-940
[136] Tundo P, Kippenberger D J, Klahn P L, et al. Functionally polymerized surfactantvesicles–synthesis and characterization [J]. J Am Chem Soc, 1982, 104(2): 456-461
[137] Tundo P, Kurihara K, Kippenberger D J, et al. Chemically dissymmetrical polymerized surfactant vesicles–synthesis and possible utilization in artificial photosynthesis [J]. Angew Chem Int Edit 1982, 21(1): 81-82
[138] Hub H H, Hupfer B, Ringsdorf H. Polymerization of lipid and lysolipid-like diacetylenes in monolayers and liposomes [J]. Am Chem Soc Coat Plast Chem, 1980, 42: 2-7
[139] Hub H H, Hupfer B, Koch H, et al. Polymerization of lipid and lysolipid-like diacetylenes in monolayers and liposomes [J]. J Macromol Sci Chem A, 1981, 15: 701-715
[140] JohnSton D S, Sanghera S, Manjon-Rubio A, et al. The formation of polymeric model biomembranes from diacetylenic fatty acids and phospholipids [J]. Biochim Biophys Acta, 1980, 602: 213-216
[141] John Ston D S, Sanghera S, Pons M, et al. Phospholipid, polymers-synthesis and spectral characteristics [J]. Biochim Biophys Acta, 1980, 602: 57-69
[142] Akimoto A, Dorn K, Gross L, et al. Polymer model membranes [J]. Angew Chem Int Ed Eng, 1981, 20: 90-91
[143] Bader H, Ringsdorf H, Skura J. Liposomes from polymerizable Glycolipids [J]. Angew Chem Int Ed Eng, 1981, 20: 91-92
[144] Gros L , Ringsdorf H , Schupp H. Polymeric antitumor agents on a molecular and on a cellular level [J]. Angew Chem Int Ed Eng, 1981, 20: 305-325
[145] Kunitake T, Nakashima N, Takarabe K, et al. Vesicles of polymeric bilayer and monolayer membranes [J]. J Am Chem Soc, 1981, 103(19): 5945-5947
[146] Lopez E, O’Brien D F, Whitesides T H. Structural effect on the photopolymerization of bilayer membranes [J]. J Am Chem Soc, 1982, 104: 305-307
[147] Regen S L, Singh A, Oehme G, et al. Polymerized phosphatidyl choline vesicles, stabilized and controllable time-release carriers [J]. J Am Chem Soc, 1981, 103:
[148] Tundo P, Prieto N E, Kippenberger D J, et al. Redox active functionally polymerized surfacetant vesicles, synthesis and characterization [J]. J Am Chem Soc, 1982, 104: 5352-5358
[149] Tundo P, Kurihara K, Prieto N E, et al. Chemically dissymmetyical polymerized surfacetant vesicles. synthesis and utilization in artificial photosynthesis [J]. J Am Chem Soc, 1982, 103:
[150] Fendler J H. Polymerized surfactant Vesicles: Novel membrane mimetic systems [J].Science, 1984, 223: 888-894
[151] Fendler J H. Membrane-mimetic approach to advanced materials (尖端材料的膜模拟) [M].江龙等译,北京:科学出版社, 1999
[152]方一非,容寿榆.双棕榈酰磷脂酰胆碱-聚-α-桐酸脂质体[J].科学通报, 1986,(17): 1338-1341
[153] Fang Y F. The polymerization ofα-Eleostearic Acid in the Dipalmitoyl- phosphatidylcholine -α-Eleostearic Acid liposome [J]. Chinese Journal of polymer Science, 1987, 5(4): 346-352
[154] Li Z C, Xie X M, Fan Q H, et al. Polyeleostearic Acid vesicles [J]. Chinese Journal of Polymer Science, 1992, 10(1): 26-31
[155]李子臣,何巍,李福绵.可聚合脂质体的研究Ⅱ-含桐酸脂质体的稳定性和穿透能力的研究[J].高分子学报, 1995, (2): 238-241
[156]李子臣.双分子层脂质体膜的稳定,修饰及性质研究[D].北京:北京大学, 1994
[157]张立群,周洪兵,周晴中,等.脂质体的聚合反应(Ⅰ) -不饱和脂质体的单体合成[J].高等学校化学学报, 1990, 11(9): 1034-1036
[158]李子臣,何巍,李福绵.可聚合脂质体的研究Ⅰ-含共轭双炔基团的两亲性单体及其脂质体[J].高分子学报, 1995, (1): 113-16
[159]于凯,孙彦,张宝申,等.共轭二炔结构类脂化合物的合成及其聚合脂质体的制备和稳定性研究[J].高等学校化学学报, 1996, 17(3): 392-395
[160]于凯.功能化聚合脂质体的合成,制备及性质[D].天津:南开大学, 1993
[161]李小奎,陈忠秀,郭纲敏,等.聚联乙炔变色囊泡技术构建及在食品安全快速检测中的应用[J].食品科技, 2010, 35(7): 303-307
[162]何巍,李子臣,李福绵.可聚合脂质体的研究Ⅲ-可缩聚氨基酸类双亲分子的合成及其脂质体[J].高分子学报, 1996, (5):615-617
[163]余作兴,赵德仁.高分子微泡的研究Ⅰ-二烯丙基二(十二烷基)季铵盐的合成与聚合[J].功能高分子学报, 1988, 1(1): 39-45
[164]陈志良,管爱国,赵德仁.高分子微泡的研究Ⅲ-二烯丙基二(十八烷基)溴化铵的制备与聚合[J].功能高分子学报, 1996, 9(3): 364-370
[165]王湘英.两亲分子聚合囊泡的合成及其对有机污染物的增溶行为[D].长沙:湖南大学, 2008
[166] Moss R A, Swarup S. Transvesicular reactions of thiols with ellman's reagent [J]. J OrgChem, 1988, 53(25): 5860-5866
[167] Fendler J H, Hinze W L. Reactivity control in micelles and surfactant vesicles. Kinetics and mechanism of base-catalyzed hydrolysis of 5,5'-dithiobis(2-nitrobenzoic acid)in Water, Hexadecyltrimethylammonium Bromide micelles, and Dioctadecyldimethyl- ammonium Chloride surfactant vesicles [J]. J Am Chem Soc, 1981, 103(18): 5439-5447
[168] Kawamuro M K, Chaimovich H, Abuin E B, et al. Evidence that the effects of synthetic amphiphile vesicles on reaction rates depend on vesicle size [J]. J Phys Chem, 1991, 95(3): 1458-1463
[169]陈向荣,丁小斌,郑朝晖,等.聚合物纳米容器的研究进展[J].化学进展, 2004, 16(3): 370-375
[170] Hoar T P, Schulman J H. Transparent water-in-oil dispersions: the oleopathic hydro- micelle [J]. Nature, 1943, 152: 102-103
[171] Shinoda K, Friberg S. Microemulsions: colloidal aspects [J]. Adv Colloid Interface Sci, 1975, 4: 281
[172] Schulman J H, Stoeckenius W, Prince L M. Mechanism of formation and structure of micro emulsions by electron microscopy [J]. J Phys Chem, 1959, 63(10): 1677-1680
[173] Danielsson I, Lindman B. The definition of microemulsion [J]. Colloids Surface, 1981, 3: 391
[174]刘会洲.微乳相萃取技术及应用[M].北京:科学出版社, 2005: 184
[175]崔正刚,殷福珊编.微乳化技术及应用[M].北京:中国轻工业出版社, 1999
[176]李干佐,郭荣等主编.微乳液理论及应用[M].北京:石油工业出版社, 1995
[177] Klier J, Tucker C J, Kalantar T H P. Properties and applications of microemulsions [J]. Adv Mater, 2000, 12(23): 1751
[178] Stoffer J O, Bone T J. Polymerization in water in oil microemulsion systems containing methyl methacrylate [J]. Dispers Sci Technol, 1980, 1: 37
[179] Stoffer J O, Bone T J. Polymerzation in water-in-oil microemulsion systems [J]. J Polym Sci Polym Chem Ed, 1980, 18: 2641-2647
[180] Candau F, Paleos C M. Polymerization in organic media, PA: Gordon Science Publication, 1992: 215
[181] Leong Y S, Candau F. Inverse microemulsion polymerization [J]. J Chem Phys ,1982, 86(13): 2269-2271
[182] Candau F, Leong Y S, Fitch R M. Kinetic study of the polymerization of acrylamide in inverse microemulsion [J]. J Polym Sci Polym Chem Ed, 1985, 23(1): 193-214
[183] Atik S S, Thomas J K. Polymerized microemul sions [J]. J Am Chem Soc, 1981, 103(14): 4279-4280
[184] Guo J S, El Aasser M S, Vanderhoff J W. Microemulsion polymerization of styrene [J]. J Polym, Sci Polym Chem Ed, 1989, 27(2): 691-710
[185] Antonietti M, Basten R, Lohmann S. Polymerization in microemulsions - a new approach to ultrafine, highly functionalized polymer dispersions [J]. Macromol Chem Phys, 1995, 196(2): 441-466
[186] Barton J. Free-radical polymerization in inverse microemulsions [J]. Prog Polym Sci, 1996, 21(3): 399-438
[187]哈润华,侯斯健,栗付平,等.微乳液结构和丙烯酰胺反相微乳液聚合[J].高分子通报, 1995, (1): 10
[188] Carver M T, H irsch E, Wittmann J C, et al. Percolation and particle nucleation in inverse microemul sion polymerization [J]. J Phys Chem, 1989, 93(12): 4867-4873
[189] CorpartM, Candau F. Aqueous solution properties of ampholytic copolymers prepared in microemulsions [J]. Marcomolecules, 1993, 26(6): 1333-1343
[190] Candau F, Leong Y S, Pouyet G, et al. Inverse microemulsion polymerization of acrylamide: Characterization of the water- in-oil microemulsions and the final microlatexes [J]. J Colloid Interf Sci, 1984, 101(1): 167-183
[191] Carver M T, Hirsch E, Wittmann J C, et al. Percolation and particle nucleation in inverse microemulsion polymerization [J]. J Phys Chem, 1989, 93(12): 4867-4873
[192] Gan L M, Chew C H, Lee K C, et al. Formation of polystyrene nanoparticles in ternary cationic microemulsions [J]. Polymer, 1994, 35(12): 2659-2664
[193] Gan L M, Lee K C, Chew C H, et al. Growth of poly(methyl methacrylate) particles in three- component cationic microemulsions [J]. J Polym Sci, Part A: Polym Chem, 1995, 33(7): 1161-1168
[194] Gan L M, Chew C H. Polymerization of styrene in water- alcohol-ionic surfactant solutions [J]. J Macromol, Sci Chem, 1983, 19: 739
[195] Chieng T H, Gan L M, Chew C H. Microporous polymer composites form microemulsion polymerization polymerizatoin of methyl methacrylate and 2-hydroxyethyl methacrylate in microemulsions [J]. Polymer, 1995, 36(10): 1941-1946
[196] Palani Raj W R, Sasthav M, Cheung H M. Microcelluar polymeric materials from microemulsions: Control of microstructure and morphology [J]. J Appl Polym Sci, 1993, 47: 499
[197] Palani Raj W R, Sasthav M, Cheung H M. Synthesis of porous polymeric membranes by polymerization of micro-emulsions [J]. Polymer, 1993, 34(15): 3305-3312
[198] Vaskova V, H louskova Z, Barton J, et al. Polymerization in inverse microemulsions, locus of initiation by ammonium peroxodisulfate and 2,2′-azoisobutyronitrile [J]. Makromol Chem, 1992, 193(3): 627-637
[199] Potisk P, Vaskova V, Capek I, et al. Polymerization of butyl acrylate in microemulsion. Locus of initiation [J]. Angew Makromol Chem, 1996, 236(1): 43-53
[200]哈润华,侯斯健. (2-甲基丙烯酰氧乙基)三甲基氯化铵-丙烯酰胺反相微乳液共聚合[J].高等学校化学学报, 1993, 14(8): 1163-1166
[201]张志成,徐相凌,张曼维.丙烯酰胺微乳液聚合[J].高分子学报, a, 1994, (4): 426; b, 1995, (1): 23
[202]高静,李晓,张卫英,等.透明多孔聚合物凝胶的微乳液合成研究[J].石油化工, 2003, 32(7): 599-603
[203]李晓,高静,张卫英,等.微乳液聚合法制备透明丙烯酸酯多孔共聚物[J].应用化学, 2003, 20(7): 655-659
[204]何天白,胡汉杰主编.功能高分子与新技术[M].北京:化学工业出版社, 2001
[205] Nunes S P, Peinemann K V. Membrane Technology:in the Chemical Industry [M]. Wiley, 2001
[206]徐建梅,张德溶.溶胶-凝胶法的技术进展与应用现状[J].地质科技情报, 1999, 18(7): 103-106
[207] Hentze H P, Antonietti M. Template synthesis of porous organic polymers [J]. Current Opinion in Solid State and Materials Science, 2001, 5: 343-353
[208]秦振平,郭红霞.模板法合成有序多孔材料研究进展[J].化工进展, 2002, 22(5): 323-327
[209] Palani Raj W R, Sasthav M, Cheung H M. Polymerization of microstructured aqueous systems formed using methyl methacrylate and potassium undecenoate [J]. Langmuir, 1992, 8(8): 1931-1936
[210] Qutubuddin S, Haque E, Benton W J, et al. Polymer association structures: microemulsions and liquid crystals [J]. ACS Symp Ser 384, 1989, Chapter 5: 64-83
[211]王龙平.双连续相微乳液聚合法制备多孔性材料的探索研究[D].福州:福州大学, 2006
[212]薛美玲,于永良.丙烯酸酯及苯乙烯微乳体系的相行为及微乳聚合[J].应用化学,2003, (10): 11-16
[213]叶强,周炜,刘华蓉等.双连续相微乳液辐射聚合制备多孔材料的研究[J].高分子学报, 2005, (1): 40-46
[214]杨杰,舒武炳,秦卫.双连续相微乳液聚合制备多孔材料[J].功能材料, 2010, 41(1): 148-152
[215] Gan L M, Liu J, Poon L P, et al. Microporous polymeric composites from bicontinuous microemulsion polymerization using a polymerizable nonionic surfactant [J]. Polymer, 1997, 38(21): 5339-5435
[216]徐相凌,殷亚东,葛学武,等.微乳液聚合研究进展[J].高等学校化学学报, 1999, 20: 478-485
[217] Gan L M, Chew C H. W/O microemulsion of polymerizable components [J]. J Dispersion Sci Technol, 1984, 5(2): 179-191
[218] Chew C H, Gan L M. Polymerization of water-in-oil microemulsions: Methyl methacrylate acrylic acid, and sodium acrylamidostearate [J]. J Polym Sci, Polym Chem Edn, 1985, 23(8): 2225-2232
[219] Gan L M, Chew C H. Microporous polymer composites from microemulsion polymerization [J]. Colloids and Surfaces A, 1997, 123-124: 681-693
[220] Paleos C M, Stassinopoulou C I, Mallaris A. Comparative studies between monomeric and polymeric sodium 10- undecenoate micelles [J]. J Phys Chem, 1983, 87(2): 251-254
[221] Gan L M, Chieng T H, Chew C H, et al. Microporous polymeric materials from microemul sion polymerization [J]. Langmuir, 1994, 10: 4022
[222] Liu J, Gan L M, Chew C H, et al. Nanostructured polymeric materials from microemulsion polymerization using Poly(ethylene oxide) Macromonomer [J]. Langmuir, 1997, 13(24): 6421-6426
[223] Schmuhl N, Davis E, Cheung H M. Morphology of thermally polymerized microporous polymer materials from methyl methacrylate and 2-hydroxyethyl methacrylate microemulsions [J]. Langmuir, 1998, 14(14): 757-761
[224] Yeoh K W, Chew C H, Gan L M, et al. Micellar polymerization of sodium 11- (N-ethylacrylamido) undecanoate : kinetics and solution properties [J]. J Macromol Sci Chem A,1990, 27(1): 63-85
[225] Chew C H, Li T D, Gan L M, et al. Synthesis and polymerization of a zwitterionic betaine surfactant: Acryloylundecyldimethylammonio acetate [J]. J Macromol Sci Pure Appl Chem A,1995, 32(2): 211-225
[226] Gan LM, Li TD, Chew CH, et al. Microporous polymeric materials from polymerization of zwitterionic microemulsions [J]. Langmuir ,1995, 11(9): 3316–20
[227] Liu J, Chew C H, Gan L M. Synthesis and polymerization of a nonionic surfactant : Poly(ethylene oxide) macromonomer [J]. J Macromol Sci Pure Appl Chem A, 1996, 33(3): 337-352
[228] Liu J, Teo W K, Chew C H, et al. Nanofiltration membranes prepared by direct microemulsion copolymerization using poly(ethylene oxide) macromonomer as a polymerizable surfactant [J]. J Appl Polym Sci, 2000, 77(12): 2785–2794
[229] Bennett D J, Burford R P, DavisT P, et al. Synthesis of porous hydrogel structures by polymerizing the continuous phase of a microemulsion [J]. Polymer International, 1995, 36(3) :219-226
[230] Menger F M, Tsuno T. Synthesis of porous polystyrene with chemically active surfaces [J]. J Am Chem Soc, 1990, 112: 6723-6732
[231] Gupta B, Singh H. Polymerization in microemulsion systems [J]. Polymer-Plastics Technology and Engineering, 1992, 31: 635-658
[232]刘杰,刘少杰,吕峰峰.微乳液体系作为药物载体的研究进展[J].日用化学工业, 2004, 34(2): 100-104
[233]刘玲霞,叶聪.微乳液聚合制备多孔材料的研究[J].安徽化工, 2005(5): 12-14
[234]黎小武,刘建强,姚志钢等.微乳液聚合制备丙烯酸酯类高吸油性树脂工艺条件的探讨[J].化学世界, 2007, (1): 56-59
[235]杨杰,舒武炳,秦卫.微乳液聚合制备多孔高吸油甲基丙烯酸酯类树脂的研究[J].高分子学报, 2010, (7): 910-917
[236] Nakashima T, Kimizuka N. Vesicles in salt: Formation of bilayer membranes from dialkyldi- methylammonium bromides in ether-containing ionic liquids [J]. Chem Lett, 2002, 31: 1018-1019
[237] Hao J C, Song A X, Wang J Z, et al. Self-assembled structure in room-temperature ionic liquids [J]. Chem Eur J, 2005, 11: 3936-3940
[238] Tang J, Li D, Sun CY, et al. Temperature dependant self-assembly of surfactant Brij76 in room temperature ionic liquid [J]. Colloids and surfaces A, 2006, 273(1-3): 24~28
[239]董彬,郑利强.离子液体参与构筑的微乳液:离子液微乳液[J].中国科学:化学, 2010, 40(9): 1266-1275
[240] Qiu Z, Texter J. Ionic liquids in microemulsions [J]. Curr Opin Colloid Interface Sci , 2008, 13: 252-262
[241] GaoH X, Li J C, Han B X, et al. Microemulsions with ionic liquid polar domains [J]. PhysChem Chem Phys, 2004, 6: 2914-2916
[242] Eastoe J, Gold S, Rogers S E, et al. Ionic liquid-in-oil microemulsions [J]. J Am Chem Soc, 2005, 127: 7302-7303
[243] GaoY A, LiN, ZhengLQ, et al. The effectofwateron the microstructure of 1-butyl-3-methylimi- dazolium tet-rafluoroborate/TX-100/benzene ionic liquid microemul-sions [J]. Chem Eur J, 2007(13): 2661-2770
[244] Gao Y A, LiN, Zheng L Q, et a.l. Role of solubilized water in the reverse ionic liquidmicroemulsion of1-butyl-3-methylimi-dazolium tetrafluoroborate/TX-100/benzene [J]. J Phys Chem B, 2007, 111: 2506-2513
[245] Li N, Gao Y A, Zheng L Q, et al. Studies on the mi-cropolarities of[bmim][BF4] /TX-100/toluene ionic liquid microemulsions andtheir behaviors characterized by UV/visible spectroscopy [ J]. Langmuir, 2007, 23: 1091-1097
[246] GaoY A, Wang S Q, Zheng L Q, et al. Microregion detection of ionic liquid microemulsions [J]. J Colloid Interface Sci, 2006, 301: 612-616
[247] GaoY A, Zhang J, Xu H Y, et al. Structural studies of 1-butyl-3-methylimidazolium tetrafluoroborate /TX-100/p-xylene ionic liquid microemulsions [J]. Chemphyschem, 2006(7): 1554-1561
[248] Atkin R, WarrG G. Phase behavior and microstructure ofmicroemulsionswith a room-temperature ionic liquid as the polar phase[ J]. J Phys Chem B, 2007, 111: 9309-9311
[249]郑永军,吾满江·艾力. Tween80/BmimPF6/醇/甲苯体系的相行为[J].物理化学学报, 2008, 24(11): 2143-2148
[250]雷达,范芳,严建芳.甲苯/TX-100 /1-丁基-3-甲基咪唑六氟磷酸盐微乳液的相结构研究[J].华中师范大学学报(自然科学版), 2007, 41(3): 403-405
[251]李娜.离子液体中分子有序组合体的研究[D].济南:山东大学, 2009
[252]戴拓苏.离子液体中两亲分子有序组合体的结构及应用研究[D].扬州:扬州大学, 2009
[253] GaoY A, Li N, Zheng L Q, et al. A cyclic voltammetric technique for the detection ofmicro-regions ofbmim-PF6 / Tween 20 / H2O microemulsions and their performance characterization by UV / Vis spectroscopy [J]. Green Chem, 2006(8): 43-49
[254] GaoY A, Han S B, Han B X, et al. TX-100 / water / 1-butyl-3-methylimidazolium hexafluorophosphate microe-mulsions [J]. Langmuir, 2005, 21: 5681-5684
[255] Cheng S Q, Fu X G, Liu J H, et al. Study of ethyleneglycol / TX-100 / ionic liquid microemulsions [J]. Colloids Surf A, 2007, 302: 211-215
[256] Friberg S E. Evaporation from an ionic liquid emulsion[J]. J Colloid Interface Sci, 2007, 307: 494-499
[257] Friberg S E, Yin Q, PavelF, et al. Solubilization of an ionic liquid, 1-butyl-3-methylimi- dazolium hexafluoro-phosphate, in a surfactant / water system [J]. J Dispers Sci Technol, 2000(2): 185-197
[258]刘丽萍.多相平衡微乳液、模板效应与离子液体调节微乳液曲率研究[D].济南:山东大学, 2009
[259]史传红. H2O/[BMIM]PF6微乳液中酶催化反应[D].济南:山东大学, 2008
[260] Yan F, Texter J. Surfactant ionic liquid-based microe-mulsions for polymerization [J]. Chem Commun, 2006,25: 2696-2698
[261] Yan F, Texter J. Solvent-reversible poration in ionic liquid copolymers [J]. Angew Chem IntEd, 2007, 46: 2440-2443
[262] Qin C K, Chai J L, Chen J F. Studies on the phase be-havior and solubilization of the microemulsion formed by surfactant-like ionic liquidswithε-β-fish-like phase diagram [J].Colloid Polym Sci, 2008, 286: 579-586
[263]秦承宽,咪唑类离子液体在微乳液中的应用及性质研究[D].济南:山东师范大学, 2008
[264]李艳.离子液体型表面活性剂表面吸附及其微乳液的相行为研究[D].济南:山东师范大学, 2010
[1]王潍平,杨锦宗.琥珀酸酯磺酸钠的合成与应用[J].化学粘合,1991, (2): 126-129
[2]葛虹.琥珀酸酯磺酸盐系列表面活性剂的合成与开发[J].表面活性剂工业, 1992, (11): 1-6
[3]常致成.磺基琥珀酸酯盐国内开发生产的技术动态浅析[J].北京日化, 1995, (3): 7-14
[4] Krystyna B, Xavier C,Chantal L. Synthesis and surfactant properties of symmetric and unsymmetric sulfosuccinic diesters,Aerosol-oT homologues [J]. J Chem Soc, Perkin Trans 2, 2001: 2179-2188
[5]李喜敏,张跃军,曲文超.壬基酚聚氧乙烯醚(n)磺基琥珀酸单酯二钠盐系列表面活性剂的合成、结构与性能[J].石油化工, 2001, 30(8): 628-630
[6]张跃军,华平.磺基琥珀酸酯盐类表面活性剂的研究进展[J].江苏化工, 2001, 29(6): 16~26
[7]李喜敏.磺基琥珀酸酯钠盐系列表面活性剂的合成与性能研究[D].南京:南京理工大学, 1998
[8]华平.磺基琥珀酸二己酯钠盐合成工艺和性能研究[D].南京:南京理工大学, 2001
[9]丛川波.琥珀酸二辛酯磺酸钠类乳化剂的合成及其微乳液性质与应用初探[D].青岛:青岛科技大学, 2004
[10] Moreland W T. Triethylamine salts in the preparation of esters from active halogen compounds [J]. J Org Chem, 1956, 21(7): 820-821
[11] Merker R L, Scott M J. The reaction of alkyl halides with carboxylic acids and phends in the presence of tertiary amines [J]. J Org Chem, 1961, 26(12): 5180-5182
[12]山下修,森山登.新颖磺基琥珀酸双酯盐的制备及其含有该成分的反应型表面活性剂组成物[P] .昭58-203960, 1983
[13] Brinchi L, Germani R, Savelli G. Ionic liquids as reaction media for esterification of carboxylate sodium salts with alkyl halides [J]. Tetrahedron Letters, 2003, 44: 2027-2029
[14] Anthony J, O'Lenick J, Wayne C S. Sulfosuccinates [J].Soap/Cosmetics/Chemical Specialties, 1988, (10): 35-40
[15]张金莲,蒋敏海,周镇江.磺基琥珀酸钠的合成与新产品开发[J].化工时刊, 1993, (9): 3-5
[16]马奉奇.温和型表面活性剂一磺基琥珀酸酯[J].辽宁化工, 1991, (6): 15-19
[17]姚志钢,李干佐,胡艾希.双子表面活性剂——二元醇双琥珀酸双酯磺酸钠(GMI-01)的合成与性能研究[J].精细化工, 2003, 20(11): 655-659
[18]姚志钢,李干佐,董凤兰,等. Gemini表面活性剂合成进展[J].化学进展, 2004, 16(3): 349-364
[19]毛培坤.表面活性剂产品工业分析[M].北京:化学工业出版社, 2003: 407-436
[1] Liu S Y, Gonzalez Y I, Kaler E W. Structural fixation of spontaneous vesicler in aqueous mixtures of polymerizable anionic and cationic surfacants [J]. Langmuir, 2003, 19: 10732-10738
[2] Wang Xiang-ying, Zeng Guang-ming, Wang Yi-lin et.al. Salt effect on polymerizable vesicles of allyl dodecyl dimethylammonium bromide and sodium dodecyl sulfonate inaqueous solution [J]. Chinese Journal of Chemistry, 2008, 26(3): 439-444
[3] Regen S L, Czech B, Singh A. Polymerized vesicles [J]. J Am Chem Soc, 1980, 102(21): 6638-6640
[4] Fendler J H. Polymerized surfactant vesicles: Novel membrane mimetic systems [J]. Science, 1984, 223: 888-894
[5] Fendier J H, Tundo P. Polymerized surfactant aggregates-characterization and utilization [J]. Acc Chem Res, 1984, 17(1): 3-8
[6]孙彦,刘敬义,于凯,等.聚合脂质体[J].有机化学, 1994, 14(5): 468-479
[7]王湘英,两亲分子聚合囊泡的合成及其对有机污染物的增溶行为[D].长沙:湖南大学, 2008
[8] Kaler E W, Murthy A K, Rodriguez B E, et al. Spontaneous vesicle formation in aqueous mixtures of single-tailed surfactants [J]. Science, NewSeries, 1989, 245(4924): 1371-1374
[9]于网林表面活性剂分子有序组合体的研究[D].北京:北京大学, 1995: 18
[10]余娜.囊泡的自发形成与其稳定性的研究[D].吉林:吉林大学, 2007: 23
[11] Yukishige K, Hirotaka U, Norio Y, et al. Spontaneous vesicle formation from aqueous solutions of didodecyldimethylammonium bromide and sodium dodecyl sulfate mixtures [J], Langmuir, 1995, 11(7): 2380-2384
[12] Winterhalter M, Helfrich W. Bending elasticity of electrically charged bilayers:coupled monolayers, neutral surfaces, and balancing stresses[J]. Z Phys Chem, 1992, 96(1): 327-330
[13] Nakashima T, Shigematsu M, Ishibashi Y, et al. Stopped-flow kinetic study on aggregation of dilauroylphosphatidic acid vesicles induced by divalent cations [J]. J Coll Interface Sci, 1990, 136(2): 447-454
[14] Carmona-Ribeiro A M, Yoshide L S,Chaimovich H. Salt effects on the stability of dioctadecyldi- methylammonium chloride and sodium dihexadecyl phosphate vesicles [J]. J Phys Chem, 1985, 89(13): 2928-2933
[15] Ohki S, Duzgunes N, Leonards k.. Phospholipid vesicle aggregation: effect of monovalent and divalent ion [J]. Biochem, 1982, 21(9): 2127-2133
[16] Inoue T, Minami H, Shimozawa R, et al. Stability of DLPA/DLPC mixed vesicles against divalent cation-induced aggregation: Importance of the hydration force [J]. J Coll Interface Sci, 1992, 152(2): 493-506
[17] Minami H, Inoue T, Shimozawa R.. Aggregation kinetics of dimyristoyl- phosphatidylglycerol vesicles induced by divalent cations [J]. J Coll Interface Sci, 1993, 158(2): 460-465
[18] Zeng J, Smish K E, Chong P L G. Effects of alcohol-induced lipid int-erdigitation on proton permeability in L-alpha-dipalmitoylphatidylcholine vesicles [J]. Biophys J, 1993, 65: 1404-1414
[19] Huang J B, Zhu B Y, Zhang Z Y. Vesicle formation of a 1:1 catanionic surfactant mixture in ethanol solution [J]. Langmuir, 1997, 13: 5759-5761
[20]孙丹.囊泡的稳定性与其在制备聚合物中空微球中的应用研究[D].吉林:吉林大学, 2008:38
[21] Ray A. Solvophobic Interactions and micelle formation in structure forming nonaqueous solvents [J]. Nature, 1971, 231: 313-315
[22] Huang J B, Zhu B Y, Zhao G X, et al. Vesicle formation of a 1:1 catanionic surfactant mixture in ethanol solution [J]. Langmuir, 1997, 13(21): 5759-5761
[23]余娜.囊泡的自发形成与其稳定性的研究[D].吉林:吉林大学, 2007: 39
[24]黄建滨,赵国玺.正负离子表面活性剂混合溶液中囊泡的稳定性[J].北京大学学报(自然科学版), 1999, 35(2):144-150
[1]郝永梅.非离子表面活性剂囊泡作为药物载体的研究[D].北京:北京大学, 2002
[2]李载常.脂质体研究进展[J].国外医学生理、病理科学与临床分册, 1999, 19(15): 3-7
[3] Rahman Y E, Cerny E A, Tollaksen S L, et al. Liposome-encapsulated actinomycin D: potential in cancer chemotherapy [J]. Proc Soc Exp Biol Med, 1974, 146(4): 1173-1176
[4] Ryman B E. The use of lipsomes as carriers of drugs and other cell modifying molecules [A]. Proc Int Congr Pharmacol 6th(Publ 1976),1975
[5] Gregoriadis G. The carrier potential of liposomes in biology and medicine [J]. New Engl J Med. 1976, 295: 704-710
[6] Lawrence M J. Surfactant systems:Microemulsions and vesicles as vehnicles for drug delivery[J]. Eur J Drug Metab Pharmacokinet, 1994, 3:257-263
[7]蔡明志,王昆.载药脂质体的物理化学稳定性的研究进展[J].国外药物科学—医药部分, 2005, 32(6): 404-407
[8]姜树红,戈延茹,汪珠燕.非离子表面活性剂囊泡的研究进展[J].中国现代药物应用, 2007, 1(11): 98-101
[9]邓英杰主编.脂质体技术[M].北京:人民卫生出版社, 2007
[10]王思玲,苏德森主编.胶体分散药物制剂[M].北京:人民卫生出版社, 2006
[11] Torchilin V P, Weissig V,脂质体[M].邓章辉,徐晖主译.北京:化学工业出版社, 2007
[12]黄义昆.脂质体作为药物载体研究进展[J].中国药师, 2005, 8(7): 549-550
[13]李唐棣,郝丽梅.脂质体包封率的研究进展[J].国外药物科学—医药部分, 2006, 33(3): 224-227
[14] Regen S L. Polymerized phosphatidylcholine vesicles as drug carriers [J]. Ann N Y Acad Sci, 1985, 446: 296-307
[15] Okada J, Cohen S, Langer R S. Oral Delvery of vaccines using polymerized liposomes [P]. US: 5,762,904, 1998
[16] Okada J, Cohen S, Langer R S. In vitro evaluation of polymerized liposomes as an oral drug delivery system [J]. Pharm Res, 1995, 12(4): 576-582
[17] Guo Caixin, Liu Shaoqin, Jiang Chang, et al. A Promising drug controlled-release system based on diacetylene/phospholipid polymerized vesicles [J]. Langmuir, 2009, 25(22): 13114-13119
[18]安娅,胡长刚,张笑一. PTA/AOT自发形成囊泡作为药物载体的缓释性研究[J].贵州师范大学学报(自然科学版), 2005, 23(3): 105-107
[19]邓英杰主编,脂质体技术[M].北京:人民卫生出版社, 2007: 128
[20]王雪超.盐酸小檗碱囊泡的制备及体内外研究[D].河北医科大学, 2009: 54
[21]陈文君,曾宪诚等.囊泡的自发形成—两类表面活性剂复配[J].科学通报, 2003, (6): 2-8
[1]胡玉山,张政朴,何炳林.高吸油性树脂[J].离子交换与吸附, 1999, 15(4): 378-384
[2] Dow Chem Co Ltd. Oil-absorbing polymer [P]. JP:昭45-27081, 1970
[3] Nippon Shokubai Co Ltd.膨润性吸油剂的制造方法[P]. JP:平05-32708, 1993
[4]李培勋,于波,卫秀成,等.吸油树脂的研究进展[J].材料工程, 2002, (10): 39-42
[5]魏徵,王源升,余红伟.高吸油性树脂的研究进展[J].材料开发与应用, 2010, 25(6): 77-80
[6]柳颖,徐明,张洪林等.高吸油树脂的研究及应用进展[J].化学与生物工程, 2009, 26(9): 7-10
[7]张高奇,周美华,梁伯润.高吸油树脂的研究与发展趋势[J].化工新型材料, 2002, 30(1): 29-31
[8]张文林,唐建军,邵拥军,等.高吸油树脂的开发与应用前景[J].天津理工学院学报, 2002, 18(2): 33-35
[9]王勇,张玉英.高吸收树脂的研究进展[J].中国塑料, 2001, 15(10): 14-17
[10]费晓峰,张季爽.高吸油树脂的研究进展[J].现代化工, 1998, (1): 13-15
[11]徐相凌,殷亚东,葛学武,等.微乳液聚合研究进展[J].高等学校化学学报, 1999, 20: 478-485
[12]高静,李晓,张卫英.双连续相微乳液聚合特征与应用[J].合成橡胶工业, 2003, (5): 319-323
[13] Gan L M, Liu J, Poon L P, et al. Microporous polymeric composites from bicontinuous microemulsion polymerization using a polymerizable nonionic surfactant [J]. Polymer, 1997, 38(21): 5339-5435
[14] Gan L M, Chieng T H, Chew C H, et al. Microporous polymeric materials from microemulsion polymerization [J]. Langmuir, 1994, 10: 4022-4027
[15] Liu J, Gan L M, Chew C H, et al. Nanostructured polymeric materials from microemulsion polymerization using poly(ethylene oxide) macromonomer [J]. Langmuir, 1997, 13(24): 6421-6426
[16] Chew C H, Li T D, Gan L H, et al. Bicontinuous-Nanostructured polymeric materials from microemulsion polymerization [J]. Langmuir, 1998, 14(21): 6068-6076
[17]杨杰,舒武炳,秦卫.微乳液聚合制备多孔高吸油甲基丙烯酸酯类树脂的研究[J].高分子学报, 2010, (7): 910-917
[18]杨俊华.高吸油性树脂[J].石油化工, 1991, (4): 39-43
[19]薛美玲,张积树,于永良等.微乳液变形及W/O型导电机理的研究[J].青岛化工学院学报, 1998, 19(1): 21-25
[20]郝京诚,郑立强,李干佐等.阳离子表面活性剂相图和微乳液结构的研究[J].山东大学学报(自然科学版), 1996, 31(2):196-200
[21]朱秀林.丙烯酸甲酯和甲基丙烯酸酯共聚及性能研究[J].高分子材料科学与工程, 1995, 11(1): 19-23
[22] Palani Raj W R, Sasthav M, Cheung H M. Microcellular polymeric materials from microemulsion control of microstructure and morphology [J]. Journal of Applied Polymer Science, 1993, 47: 499-511
[1]高静.微乳液聚合制备透明多孔MMA-BA共聚物[D].福州:福州大学, 2003
[2] Yue D M,Yu J, Zhang Q, et al. Preparation of nano-porous materials(I) by polymerization of amphiphile self-assemblies [J]. Chem Res Chinese U, 2003, 19(1): 112-119
[3] Hentze H P, Antonietti M. Template synthesis of porous organic polymers [J]. Current Opinion in Solid State and Materials Science, 2001, 5: 343–353
[4] Gan L M, Chew C H. Polymerization in the transparent water-in-oil solutions I: Methyl methacrylate and the copolymerizable cosurfactant [J]. J Dispersion Sci Technol, 1983, 4(3): 291-312
[5] Palani Raj W R, Sasthav M, Cheung H M. Synthesis of porous polymeric membranes by polymerization of micro-emulsions [J]. Polymer, 1993, 34(15): 3305-3312
[6] Liu J, Gan L M, Chew C H, et al. Nanostructured polymeric materials from microemulsion polymerization using poly(ethylene oxide) macromonomer [J]. Langmuir, 1997, 13(24): 6421-6426
[7] Chew C H, Li T D, Gan L H, et al. Bicontinuous-Nanostructured Polymeric Materials from Microemulsion Polymerization [J], Langmuir, 1998, 14(21): 6068-6076
[8] Gan L M, Liu J, Poon L P, et al. Microporous polymeric composites from bicontinuous microemulsion polymerization using a polymerizable nonionic surfactant [J]. Polymer, 1997, 38(21): 5339-5435
[9] Welton T. Room-Temperature ionic liquids solvents for synthesis and catalysis[J]. Chem Rev, 1999, 99: 2071-2084
[10]李汝雄.绿色溶剂-离子液体的合成与应用[M].北京:化学工业出版社, 2004: 3-9
[11]张建玲,韩布兴,程四清.离子液体相关微乳液体系[R].北京:中国科学院化学研究所, 2007
[12]张国栋,陈晓,靖波.室温离子液体中的有序分子组合体[J].化学进展, 2006, 18: 1085-1091
[13] Friberg S E. Evaporation from an ionic liquid emulsion[J]. J Colloid Interface Sci, 2007, 307: 494-499
[14] Eastoe J, Gold S, Rogers S E, et al. Ionic liquid-in-oil microemulsions [J]. J Am Chem Soc, 2005, 127: 7302-7303
[15] Kubisa P. Application of ionic liquids as solvents for polymerization processes[J]. Prog Polym Sci, 2004, 29(1): 3-12
[16]陈珍珍.离子液体微乳液中原子转移自由基聚合研究[D].苏州:苏州大学, 2010
[17] Yu Shaomei, Yan Feng , Zhang Xingwang, et al. Polymerization of ionic liquid-based microemulsions: A versatile method for the synthesis of polymer electrolytes[J]. Macromolecules, 2008, 41: 3389-3392
[18]俞绍玫.基于离子液体微乳液的研究及其功能聚合物材料的研究[D].苏州:苏州大学, 2009
[19] Yan Feng, Yu Shaomei, Zhang Xingwang, et al. Enhanced proton conduction in polymer electrolyte membranes as synthesized by polymerization of protic ionic liquid-based microemulsions[J]. Chem Mater, 2009, 21: 1480–1484
[20] Yan F,Texter J. Surfactant ionic liquid-based microemulsions for polymerization[J]. Chem.Commun, 2006, 25: 2696-2698
[21] Yan F, Texter J. Solvent-reversible poration in ionic liquid copolymers [J]. Angew Chem Int Ed, 2007, 46: 2440-2443g
[22]周舟,何德良,李雪玲等.聚苯胺在离子液体/水体系中的微乳液法合成[J].高分子学报, 2007, (8): 757-760
[23]周舟.室温离子液体中纳米导电聚合物材料的制备[D].长沙:湖南大学, 2009
[24]郭艳妮.离子液体型导电聚合物纳米材料的制备与表征[D].长沙:湖南大学, 2010
[25]钟建芳.离子液体中羟基新戊醛的电化学行为和导电聚苯胺的制备[D].长沙:湖南大学, 2008
[26] Chieng T H, Gan L M, Chew C H, et al. Formation of microporous polymeric materials by microemulsion polymerization of methyl methacrylate and 2-hydroxyethyl methacrylate [J]. J Appl Polym Sci, 1996, 60(10): 1561-1564
[27] Gan L M, Chew C H. Microporous polymer composites from microemulsion polymerization [J]. Colloids and Surfaces A, 1997, 123-124: 681-693
[28] Burban J H, Mengtrao He, Cussler E L. Organic microporous materials made by bicontinuous microemulsion polymerization [J]. AIChE Journal, 1995, 41(4): 907-914
[29] Palani Raj W R, Sasthav M, Cheung H M. Microcellular polymeric materials from microemulsion control of microstructure and morphology [J]. J Appl Polym Sci, 1993, 47: 499-511