电致型形状记忆聚合物的研究进展
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摘要
介绍了电致型形状记忆聚合物的形状记忆机理、制备与表征方法,探讨了碳纳米管、炭黑、石墨烯及金属纳米粒子对电致形状记忆效应的影响,综述了电致型形状记忆聚合物的最新研究进展,提出了未来的研究方向和需要解决的问题。
The shape memory mechanism, preparation and characterization methods of electro-active shape memory polymers were introduced. The influences of carbon nanotubes, carbon black, graphene and metal nanoparticles on the electro-active shape memory effect were discussed. And the latest research progress in electro-active shape memory polymers was reviewed with 44 references, and future research directions and problems to be solved were proposed.
The shape memory mechanism, preparation and characterization methods of electro-active shape memory polymers were introduced. The influences of carbon nanotubes, carbon black, graphene and metal nanoparticles on the electro-active shape memory effect were discussed. And the latest research progress in electro-active shape memory polymers was reviewed with 44 references, and future research directions and problems to be solved were proposed.
引文
[1] Abishera R,Velmurugan R,Gopal K V N.Reversible plasticity shape memory effect in carbon nanotubes reinforced epoxy nanocomposites[J].Composites Science & Technology,2016,137(12):148-158.
[2] Sabzi M,Babaahmadi M,Rahnama M.Thermally and electrically triggered triple-shape memory behavior of poly(vinyl acetate)/poly(lactic acid) due to graphene-induced phase separation[J].Acs Appl Mater Interfaces,2017,9(28):24061.
[3] Li Yuzhan,Rios O,Keum J K,et al.Photo responsive liquid crystalline epoxy networks with shape memory behavior and dynamic ester bonds[J].Acs Applied Materials & Interfaces,2016,8(24):15750.
[4] Singamaneni S,Bliznyuk V N,Binek C,et al.Magnetic nanoparticles:Recent advances in synthesis,self-assembly and applications[J].Journal of Materials Chemistry,2011,21(42):16819-16845.
[5] Bai Shuo,Zou Hua,Dietsch H,et al.Functional iron oxide nanoparticles as reversible crosslinks for magnetically addressable shape-memory polymers[J].Macromolecular Chemistry & Physics,2014,215(5):398–404.
[6] Khan F,Singh K.An experimental investigation of the effect of strain on the electrical conductivity of a shape memory polymer[J].Polymer Testing,2016,49(4):82-87.
[7] Liu Tianzhen,Zhou Tianyang,Yao Yongtao,et al.Stimulus methods of multi-functional shape memory polymer nanocomposites:A review[J].Composites (Part A:Applied Science & Manufacturing),2017,100(6):20-30.
[8] Yao Yongtao,Zhou Tianyang,Wang Jingjie,et al."Two way" shape memory composites based on electro-active polymer and thermoplastic membrane[J].Composites (Part A:Applied Science & Manufacturing),2016,90(11):502-509.
[9] Feng Xianqi ,Zhang Gongzheng,Zhuo Shuyun,et al.Dual responsive shape memory polymer/clay nanocomposites[J].Composites Science & Technology,2016,129(6):53-60.
[10] Xie Tao.Recent advances in polymer shape memory[J].Polymer,2011,52(22):4985-5000.
[11] Naguib H E.Design and characterization of biocompatible shape memory polymer (SMP) blend foams with a dynamic porous structure[J].Polymer,2015,56(1):82-92.
[12] Liu Wei ,Zhang Ruoyu ,Huang Miaoming,et al.Synthesis and shape memory property of segmented poly(ester urethane) with poly(butylene 1,4-cyclohexanedicarboxylate) as the soft segment[J].Rsc Advances,2016,6(98):95527-95534.
[13] Zhang Zhixing,Wang Wenyan,Yang Jinghui,et al.Excellent electroactive shape memory performance of EVA/PCL/CNT blend composites with selectively localized CNTs[J].Journal of Physical Chemistry,2016,120(40) :22793-22802.
[14] Santo L.Shape memory polymer foams[J].Progress in Aerospace Sciences,2016,81(2):60-65.
[15] Song Shijie,Feng Jiachun,Wu Peiyi.A new strategy to prepare polymer-based shape memory elastomers[J].Macromole-cular Rapid Communications,2011,32(19):1569-1575.
[16] Wang Wenxin,Liu Yanju,Leng Jinsong.Recent developments in shape memory polymer nanocomposites:Actuation methods and mechanisms[J].Coordination Chemistry Reviews,2016,320(8):38-52.
[17] Lu Haibao,Yao Yongtao,Yin Jinying,et al.Functionally graded carbon nanotube and nafion/silica nanofibre for electrical actuation of carbon fibre reinforced shape memory polymer[J].Pigment & Resin Technology,2016,45(2):93-98.
[18] Zhang Xuhui,Tang Zhenghai ,Guo Baochun.Reversible plasticity shape memory polymers:Key factors and applications[J].Journal of Polymer Science (Part B:Polymer Physics),2016,54(14):1295-1299.
[19] Deng Zexing,Guo Yi,Zhao Xin,et al.Stretchable degradable and electroactive shape memory copolymers with tunable recovery temperature enhancing myogenic differentiation.[J].Acta Biomaterialia,2016,46(12):234-244.
[20] Zhang Zhixing ,He Zhenzhen,Yang Jinghui,et al.Crystallization controlled shape memory behaviors of dynamically vulcanized poly( l-lactide)/poly(ethylene vinyl acetate) blends[J].Polymer Testing,2016,51(6):82-92.
[21] Xiu Hao,Zhou Yan,Dai Jia,et al.Formation of new electric double percolation via carbon black induced co-continuous like morphology[J].Rsc Advances,2014,4(70):37193-37196.
[22] Liu Tianyu,Huang Rui,Qi Xiaodong,et al.Facile preparation of rapidly electro-active shape memory thermoplastic polyurethane/polylactide blends via phase morphology control and incorporation of conductive fillers[J].Polymer,2017,114(4):28-35.
[23] Qi Xiaodong,Dong Peng,Liu Zhenwei,et al.Selective localization of multi-walled carbon nanotubes in bi-component biodegradable polyester blend for rapid electroactive shape memory performance[J].Composites Science & Technology,2016,125(6):38-46.
[24] Zhou Jie,Li Hua,Tian Ran,et al.Fabricating fast triggered electro-active shape memory graphite/silver nanowires/epoxy resin composite from polymer template[J].Scientific Reports,2017,7(1):5535.
[25] Yang Chaojin,Huang Ting,Yang Jinghui,et al.Carbon nanotubes induced brittle-ductile transition behavior of the polypropylene/ethylene-propylene-diene terpolymer blends[J].Composites Science & Technology,2017,139(2):109-116.
[26] Wang Xin,Sparkman J,Gou Jiahua.Electrical actuation and shape memory behavior of polyurethane composites incorporated with printed carbon nanotube layers[J].Composites Science & Technology,2017,141(3):8-15.
[27] Zhou Jie,Li Hua,Liu Weiwei,et al.A facile method to fabricate polyurethane based graphene foams/epoxy/carbon nanotubes composite for electro-active shape memory application[J].Composites (Part A:Applied Science & Manufactu-ring),2016,91(12):292-300.
[28] Lu Haibao,Yin Jinying,Xu Ben,et al.Synergistic effects of carboxylic acid-functionalized carbon nanotube and nafion/silica nanofiber on electrical actuation efficiency of shape memory polymer nanocomposite[J].Composites (Part B:Enginee-ring),2016,100(9):146-151.
[29] Bai Qiqi,Wei Xiao,Yang Jinghui,et al.Dispersion and network formation of graphene platelets in polystyrene composites and the resultant conductive properties[J].Composites (Part A:Applied Science & Manufacturing),2017,96(5):89-98.
[30] Khatua B B,Maiti S,Shrivastava N K,et al.A strategy for achieving low percolation and high electrical conductivity in melt-blended polycarbonate (PC)/multiwall carbon nanotube (MWCNT) nanocomposites:Electrical and thermo-mechanical properties[J].Express Polymer Letters,2013,7(6):505-518.
[31] Zhang Tingting,Yang Jinghui,Zhang Nan,et al.Achieving large dielectric property improvement in poly(ethylene vinyl acetate)/thermoplastic polyurethane/multiwall carbon nanotube nanocomposites by tailoring phase morphology[J].Industrial & Engineering Chemistry Research,2017,56(13):3607-3617.
[32] Gunes I S,Cao Feina,Jana S C.Evaluation of nanoparticulate fillers for development of shape memory polyurethane nanocomposites[J].Polymer,2008,49(9):2223-2234.
[33] Qi Xiaodong,Xiu Hao,Wei Yuan,et al.Enhanced shape memory property of polylactide/thermoplastic poly(ether)urethane composites via carbon black self-networking induced co-continuous structure[J].Composites Science & Technology,2017,139(2):8-16.
[34] Lan Xin,Liu Liwu,Liu Yanju,et al.Thermomechanical and electroactive behavior of a thermosetting styrene-based carbon black shape-memory composite[J].Journal of Applied Polymer Science,2018,135(13):45978.
[35] Xiao Yanjun,Wang Wenyan,Chen Xijia,et al.Hybrid network structure and thermal conductive properties in poly(vinylidene fluoride) composites based on carbon nanotubes and graphene nanoplatelets[J].Composites (Part A:Applied Science & Manufacturing),2016,90(11):614-625.
[36] Achaby M E,Arrakhiz F E,Vaudreuil S,et al.Mechanical,thermal,and rheological properties of graphene-based polypropylene nanocomposites prepared by melt mixing[J].Polymer Composites,2012,33(5):733–744.
[37] Mao Hanjun,Zhang Tingting,Huang Ting,et al.Fabrication of poly(vinylidene fluoride)/nylon 6/carbon nanotube nanocomposites through selective localization of carbon nanotubes in blends[J].Polymer International,2017,66(4):604-611.
[38] Kim J T,Kim B K,Kim E Y,et al.Synthesis and shape memory performance of polyurethane/graphene nanocomposites[J].Reactive & Functional Polymers,2014,74(1):16-21.
[39] Han S.Preparation of polyurethane nanocomposites via covalent incorporation of functionalized graphene and its shape memory effect[J].Composites (Part A:Applied Science & Manufacturing),2014,58(58):65-72.
[40] Sabzi M,Babaahmadi M,Samadi N,et al.Graphene network enabled high speed electrical actuation of shape memory nanocomposite based on poly(vinyl acetate)[J].Polymer International,2016,66(5):323-330.
[41] Zhang Zhixing,Dou Jiaqi,He Jiehao,et al.Electrically/infrared actuated shape memory composites based on a bio-based polyester blend and graphene nanoplatelets and their excellent self-driven ability[J].Journal of Materials Chemistry,2017,5(5):4145.
[42] Wu Yunhui,Liu Haizhou,Song Chen,et al.Channel crack-designed gold PU sponge for highly elastic piezoresistive sensor with excellent detectability[J].Acs Applied Materials & Interfaces,2017,9(23):20098.
[43] Deng Junkai,Chang Zhenyue,Zhao Tong,et al.Electric field induced reversible phase transition in Li doped phosphorene:Shape memory effect and superelasticity[J].Journal of the American Chemical Society,2016,138(14):4772-4778.
[44] Chen Jie,Zhang Zhixing,Huang Wenbin,et al.Carbon nanotube network structure induced strain sensitivity and shape memory behavior changes of thermoplastic polyurethane[J].Materials & Design,2015,69(69):105-113.
[2] Sabzi M,Babaahmadi M,Rahnama M.Thermally and electrically triggered triple-shape memory behavior of poly(vinyl acetate)/poly(lactic acid) due to graphene-induced phase separation[J].Acs Appl Mater Interfaces,2017,9(28):24061.
[3] Li Yuzhan,Rios O,Keum J K,et al.Photo responsive liquid crystalline epoxy networks with shape memory behavior and dynamic ester bonds[J].Acs Applied Materials & Interfaces,2016,8(24):15750.
[4] Singamaneni S,Bliznyuk V N,Binek C,et al.Magnetic nanoparticles:Recent advances in synthesis,self-assembly and applications[J].Journal of Materials Chemistry,2011,21(42):16819-16845.
[5] Bai Shuo,Zou Hua,Dietsch H,et al.Functional iron oxide nanoparticles as reversible crosslinks for magnetically addressable shape-memory polymers[J].Macromolecular Chemistry & Physics,2014,215(5):398–404.
[6] Khan F,Singh K.An experimental investigation of the effect of strain on the electrical conductivity of a shape memory polymer[J].Polymer Testing,2016,49(4):82-87.
[7] Liu Tianzhen,Zhou Tianyang,Yao Yongtao,et al.Stimulus methods of multi-functional shape memory polymer nanocomposites:A review[J].Composites (Part A:Applied Science & Manufacturing),2017,100(6):20-30.
[8] Yao Yongtao,Zhou Tianyang,Wang Jingjie,et al."Two way" shape memory composites based on electro-active polymer and thermoplastic membrane[J].Composites (Part A:Applied Science & Manufacturing),2016,90(11):502-509.
[9] Feng Xianqi ,Zhang Gongzheng,Zhuo Shuyun,et al.Dual responsive shape memory polymer/clay nanocomposites[J].Composites Science & Technology,2016,129(6):53-60.
[10] Xie Tao.Recent advances in polymer shape memory[J].Polymer,2011,52(22):4985-5000.
[11] Naguib H E.Design and characterization of biocompatible shape memory polymer (SMP) blend foams with a dynamic porous structure[J].Polymer,2015,56(1):82-92.
[12] Liu Wei ,Zhang Ruoyu ,Huang Miaoming,et al.Synthesis and shape memory property of segmented poly(ester urethane) with poly(butylene 1,4-cyclohexanedicarboxylate) as the soft segment[J].Rsc Advances,2016,6(98):95527-95534.
[13] Zhang Zhixing,Wang Wenyan,Yang Jinghui,et al.Excellent electroactive shape memory performance of EVA/PCL/CNT blend composites with selectively localized CNTs[J].Journal of Physical Chemistry,2016,120(40) :22793-22802.
[14] Santo L.Shape memory polymer foams[J].Progress in Aerospace Sciences,2016,81(2):60-65.
[15] Song Shijie,Feng Jiachun,Wu Peiyi.A new strategy to prepare polymer-based shape memory elastomers[J].Macromole-cular Rapid Communications,2011,32(19):1569-1575.
[16] Wang Wenxin,Liu Yanju,Leng Jinsong.Recent developments in shape memory polymer nanocomposites:Actuation methods and mechanisms[J].Coordination Chemistry Reviews,2016,320(8):38-52.
[17] Lu Haibao,Yao Yongtao,Yin Jinying,et al.Functionally graded carbon nanotube and nafion/silica nanofibre for electrical actuation of carbon fibre reinforced shape memory polymer[J].Pigment & Resin Technology,2016,45(2):93-98.
[18] Zhang Xuhui,Tang Zhenghai ,Guo Baochun.Reversible plasticity shape memory polymers:Key factors and applications[J].Journal of Polymer Science (Part B:Polymer Physics),2016,54(14):1295-1299.
[19] Deng Zexing,Guo Yi,Zhao Xin,et al.Stretchable degradable and electroactive shape memory copolymers with tunable recovery temperature enhancing myogenic differentiation.[J].Acta Biomaterialia,2016,46(12):234-244.
[20] Zhang Zhixing ,He Zhenzhen,Yang Jinghui,et al.Crystallization controlled shape memory behaviors of dynamically vulcanized poly( l-lactide)/poly(ethylene vinyl acetate) blends[J].Polymer Testing,2016,51(6):82-92.
[21] Xiu Hao,Zhou Yan,Dai Jia,et al.Formation of new electric double percolation via carbon black induced co-continuous like morphology[J].Rsc Advances,2014,4(70):37193-37196.
[22] Liu Tianyu,Huang Rui,Qi Xiaodong,et al.Facile preparation of rapidly electro-active shape memory thermoplastic polyurethane/polylactide blends via phase morphology control and incorporation of conductive fillers[J].Polymer,2017,114(4):28-35.
[23] Qi Xiaodong,Dong Peng,Liu Zhenwei,et al.Selective localization of multi-walled carbon nanotubes in bi-component biodegradable polyester blend for rapid electroactive shape memory performance[J].Composites Science & Technology,2016,125(6):38-46.
[24] Zhou Jie,Li Hua,Tian Ran,et al.Fabricating fast triggered electro-active shape memory graphite/silver nanowires/epoxy resin composite from polymer template[J].Scientific Reports,2017,7(1):5535.
[25] Yang Chaojin,Huang Ting,Yang Jinghui,et al.Carbon nanotubes induced brittle-ductile transition behavior of the polypropylene/ethylene-propylene-diene terpolymer blends[J].Composites Science & Technology,2017,139(2):109-116.
[26] Wang Xin,Sparkman J,Gou Jiahua.Electrical actuation and shape memory behavior of polyurethane composites incorporated with printed carbon nanotube layers[J].Composites Science & Technology,2017,141(3):8-15.
[27] Zhou Jie,Li Hua,Liu Weiwei,et al.A facile method to fabricate polyurethane based graphene foams/epoxy/carbon nanotubes composite for electro-active shape memory application[J].Composites (Part A:Applied Science & Manufactu-ring),2016,91(12):292-300.
[28] Lu Haibao,Yin Jinying,Xu Ben,et al.Synergistic effects of carboxylic acid-functionalized carbon nanotube and nafion/silica nanofiber on electrical actuation efficiency of shape memory polymer nanocomposite[J].Composites (Part B:Enginee-ring),2016,100(9):146-151.
[29] Bai Qiqi,Wei Xiao,Yang Jinghui,et al.Dispersion and network formation of graphene platelets in polystyrene composites and the resultant conductive properties[J].Composites (Part A:Applied Science & Manufacturing),2017,96(5):89-98.
[30] Khatua B B,Maiti S,Shrivastava N K,et al.A strategy for achieving low percolation and high electrical conductivity in melt-blended polycarbonate (PC)/multiwall carbon nanotube (MWCNT) nanocomposites:Electrical and thermo-mechanical properties[J].Express Polymer Letters,2013,7(6):505-518.
[31] Zhang Tingting,Yang Jinghui,Zhang Nan,et al.Achieving large dielectric property improvement in poly(ethylene vinyl acetate)/thermoplastic polyurethane/multiwall carbon nanotube nanocomposites by tailoring phase morphology[J].Industrial & Engineering Chemistry Research,2017,56(13):3607-3617.
[32] Gunes I S,Cao Feina,Jana S C.Evaluation of nanoparticulate fillers for development of shape memory polyurethane nanocomposites[J].Polymer,2008,49(9):2223-2234.
[33] Qi Xiaodong,Xiu Hao,Wei Yuan,et al.Enhanced shape memory property of polylactide/thermoplastic poly(ether)urethane composites via carbon black self-networking induced co-continuous structure[J].Composites Science & Technology,2017,139(2):8-16.
[34] Lan Xin,Liu Liwu,Liu Yanju,et al.Thermomechanical and electroactive behavior of a thermosetting styrene-based carbon black shape-memory composite[J].Journal of Applied Polymer Science,2018,135(13):45978.
[35] Xiao Yanjun,Wang Wenyan,Chen Xijia,et al.Hybrid network structure and thermal conductive properties in poly(vinylidene fluoride) composites based on carbon nanotubes and graphene nanoplatelets[J].Composites (Part A:Applied Science & Manufacturing),2016,90(11):614-625.
[36] Achaby M E,Arrakhiz F E,Vaudreuil S,et al.Mechanical,thermal,and rheological properties of graphene-based polypropylene nanocomposites prepared by melt mixing[J].Polymer Composites,2012,33(5):733–744.
[37] Mao Hanjun,Zhang Tingting,Huang Ting,et al.Fabrication of poly(vinylidene fluoride)/nylon 6/carbon nanotube nanocomposites through selective localization of carbon nanotubes in blends[J].Polymer International,2017,66(4):604-611.
[38] Kim J T,Kim B K,Kim E Y,et al.Synthesis and shape memory performance of polyurethane/graphene nanocomposites[J].Reactive & Functional Polymers,2014,74(1):16-21.
[39] Han S.Preparation of polyurethane nanocomposites via covalent incorporation of functionalized graphene and its shape memory effect[J].Composites (Part A:Applied Science & Manufacturing),2014,58(58):65-72.
[40] Sabzi M,Babaahmadi M,Samadi N,et al.Graphene network enabled high speed electrical actuation of shape memory nanocomposite based on poly(vinyl acetate)[J].Polymer International,2016,66(5):323-330.
[41] Zhang Zhixing,Dou Jiaqi,He Jiehao,et al.Electrically/infrared actuated shape memory composites based on a bio-based polyester blend and graphene nanoplatelets and their excellent self-driven ability[J].Journal of Materials Chemistry,2017,5(5):4145.
[42] Wu Yunhui,Liu Haizhou,Song Chen,et al.Channel crack-designed gold PU sponge for highly elastic piezoresistive sensor with excellent detectability[J].Acs Applied Materials & Interfaces,2017,9(23):20098.
[43] Deng Junkai,Chang Zhenyue,Zhao Tong,et al.Electric field induced reversible phase transition in Li doped phosphorene:Shape memory effect and superelasticity[J].Journal of the American Chemical Society,2016,138(14):4772-4778.
[44] Chen Jie,Zhang Zhixing,Huang Wenbin,et al.Carbon nanotube network structure induced strain sensitivity and shape memory behavior changes of thermoplastic polyurethane[J].Materials & Design,2015,69(69):105-113.