高分子量聚苯胺/碳纳米管复合材料的合成与表征

在导电聚合物中,聚苯胺（PANI）因其导电性能优良,环境稳定性好,合成工艺简单,原料成本低廉等优点,被认为是最有可能实际应用的导电聚合物．然而用传统方法合成的聚苯胺由于其分子量小,分子链中存在缺陷而使其导电性能和力学性能大大降低,从而限制了其实际应用．而高分子量聚苯胺的导电性能和力学性能比一般聚苯胺有较大的提高．     

利用天然生物分子合成导电聚苯胺的研究

本文综述了利用多种不同的天然生物分子如蛋白质(包括酶和氨基酸)、糖类、核酸、多巴胺和柠檬汁等为模板合成导电聚苯胺的研究进展。本文首先介绍了这些天然生物分子对产物聚苯胺的手性、导电率、形态以及其它方面性质的影响,归纳了利用天然生物分子合成导电聚苯胺的研究进展,然后分析了导电聚苯胺合成过程中面临的问题并对该领域的未来发展进行了展望,以期为制备性质优良和环境友好的新型导电聚苯胺材料提供有益的参考。     

导电聚合物超级电容器电极材料*

导电聚合物（聚苯胺,聚吡咯,聚噻吩）作为超级电容器电极材料的研究引起了人们广泛的兴趣,该类材料制备的超级电容器具有成本低、容量高、充放电时间短、环境友好和安全性高等优点。本文综述了近年来基于导电聚合物及其与无机材料（碳材料/金属氧化物材料）复合所得电极材料在超级电容器中的应用进展,指出具有纳米结构导电聚合物材料及导电聚合物与无机纳米材料的复合是超级电容器电极材料研究的重要发展方向。     

导电聚苯胺/橡胶复合材料的研究进展

聚苯胺是一种结构型导电高分子,因其特殊的结构和优异的物理化学性能,使它在二次电池、金属防腐、传感器、电容器、电磁屏蔽及抗静电等领域有着广泛而深入的应用前景。本文概述了导电聚苯胺的结构和特性,主要综述了聚苯胺/橡胶基复合材料的制备方法。其制备方法主要有共混法和聚合法,共混法主要有机械熔融共混法、溶液共混法和乳液共混法;聚合法主要包括电化学聚合、原位乳液聚合法、吸附聚合法等,总结了聚苯胺/橡胶基复合材料的研究情况及发展应用。     

超级电容器石墨烯-聚苯胺复合材料的研究进展

超级电容器具有功率密度高、充放电速度快、循环寿命长和维护成本低的特点,在电动车动力电池领域具有潜在的应用前景。超级电容器性能主要由其电极材料所决定。聚苯胺易合成、理论比容量高,而且导电性能优异,作为超级电容器电极材料有很高的应用价值。但是,在长期使用过程中,它的体积容易发生膨胀或收缩,循环寿命差。为了解决这个问题,将聚苯胺与石墨烯复合可以扬长避短,充分利用两者之间的协同效应,赋予复合材料优异电化学电容性能。本文综述了超级电容器用石墨烯-聚苯胺复合材料的制备方法,包括原位聚合法、油水界面合成法、电化学合成法、层层自组装法等;提出了三维网状石墨烯和对石墨烯-聚苯胺复合材料进行改性来提高复合材料的电化学电容性能的思路。     

掺杂和取代对聚苯胺导电性能影响机制的研究

在导电聚合物的研究中，聚苯胺及其衍生物一直是人们相当感兴趣的课题．此类聚合物既可用氧化剂掺杂，也可进行质子酸掺杂，掺杂后其电导率可提高约十个数量级｛1，’］；利用在主链上引入取代基等化学修饰方法，可方便地调节其溶解性、加工性等物理化学性能．已有的研究结果表明，主链的化学修饰往往给聚苯胺的导电性能带来不利影响＊．因此，如何使聚苯胶类导电聚合物保持高的电导率且同时具备优良的物理加工性能使成为此类导电聚合物研究中的一个亟待解决的问题一本文利用鼻子化学EHMO－CO方法对掺杂和取代影响聚苯胺及其衍生物导电性…     

超级电容器用石墨烯-聚苯胺复合材料的研究进展

超级电容器具有功率密度高、充放电速度快、循环寿命长和维护成本低的特点,在电动车动力电池领域具有潜在的应用前景。超级电容器性能主要由其电极材料所决定。聚苯胺易合成、理论比容量高,而且导电性能优异,作为超级电容器电极材料有很高的应用价值。但是,在长期使用过程中,它的体积容易发生膨胀或收缩,循环寿命差。为了解决这个问题,将聚苯胺与石墨烯复合可以扬长避短,充分利用两者之间的协同效应,赋予复合材料优异电化学电容性能。本文综述了超级电容器用石墨烯-聚苯胺复合材料的制备方法,包括原位聚合法、油水界面合成法、电化学合成法、层层自组装法等;提出了三维网状石墨烯和对石墨烯-聚苯胺复合材料进行改性来提高复合材料的电化学电容性能的思路。     

我国导电聚苯胺材料研发获系列创新成果

中科院长春应化所和吉林正基科技开发有限责任公司的科技人员经过4年努力，在导电聚苯胺材料的研发方面获得了系列创新成果：在国内建立了第1条年产百吨的导电聚苯胺原料生产线、第1条年产千吨的导电聚苯胺涂料生产线；率先在国内研发出具有我国自主知识产权的聚苯胺防腐涂料、聚苯胺防腐油脂、聚苯胺防腐密封胶、聚苯胺防冻液防腐添加剂等系列高附加值聚苯胺下游产品。     

石墨烯/聚苯胺复合材料在超级电容器中的研究进展

聚苯胺理论比容量高,具有优良的导电性能,是理想的超级电容器电极材料。但是,在长期的充放电过程中容易发生体积的收缩与膨胀,循环寿命差。同时,石墨烯由于具有高的理论比表面积,被广泛用作超级电容器电极材料。将聚苯胺与石墨烯复合,利用二者的协同作用,使复合材料具有优异的电化学性能。本文综述了石墨烯/聚苯胺复合材料的制备方法以及近年来在超级电容器领域的主要研究成果,并就其目前存在的主要问题进行了讨论,最后对石墨烯/聚苯胺复合材料的前景进行了展望。     

浸渍聚合法制备透明导电聚苯胺薄膜的研究

采用浸渍聚合法制备透明导电的聚苯胺薄膜，并系统地研究了基片、反应温度、氧化剂和掺杂剂等因素对聚苯胺透明导电薄膜的电学和光学性能的影响．在最佳的制备条件下，所得薄膜的室温电导率可达１～５Ｓ／ｃｍ．当厚度为０５μｍ时，在４５０至６５０ｎｍ的透光窗口内，该薄膜的透光率可达８０％．借助结构表征讨论了薄膜的生长机理和它的结构组成．     

Metallized nanotube polymer composites via supercritical fluid impregnation

Although many metal decorated nanotubes and nanowires appear in the literature, well‐dispersed metal decorated nanotube polymer composites have rarely been reported because of the excessive density mismatch between the decorated nanotubes and polymer matrix. Here, we report a novel method to prepare well‐dispersed, highly functional, metallized nanotube polymer composites (MNPCs) that possess remarkably improved electrical conductivity and mechanical toughness. The MNPCs are prepared by supercritical fluid impregnation of an organometal compound into a premade well‐dispersed single wall carbon nanotube‐polymer composite film. The infused precursor preferentially migrates towards the nanotubes to undergo spontaneous reduction and form nanometer‐scale metal particles leading to an increase in the conductivity of the MNPC films. The environmentally friendly supercritical fluid impregnation process significantly improved the toughness of the composite films, regardless of the presence of metal. Additional functionality can be imparted into the resulting MNPC by infusing other precursors such as magnetic and catalytic metal compounds. © 2011 Wiley Periodicals, Inc.* J Polym Sci Part B: Polym Phys, 2012     

Composites based on polyaniline and aligned carbon nanotubes

Composites based on aligned carbon nanotubes and polyaniline are prepared via the electrochemical polycondensation of aniline in a sulf uric acid solution. The structure of the composites and the character of interaction of polyaniline and the surface of carbon nanotubes are studied by scanning and transmission electron microscopy, X-ray diffraction, and IR and X-ra y photoelectron spectroscopy. It is shown that in the composites, electron density is transferred from the carbon nanotube to the polyaniline film. The occurrence of polyaniline on the surface of nanotubes increases the mean current in cyclic voltammograms of the composite material and leads to a marked increase in the calculated specific capacity of electrodes formed on its basis.     

ZnO纳米线基MWNTs/PVDF复合热电材料的制备及特性研究

将不同比例的多壁碳管(MWNTs)与聚偏二氟乙烯(PVDF)聚合物混合后,喷涂于n型ZnO半导体纳米线阵列上,制备了一种新型ZnO纳米线基MWNTs/PVDF热电复合材料.与以往采用价格昂贵的p型与n型单壁碳纳米管(SWNTs)与聚合物混合制备的复合热电材料特性相比,这种新型热电复合材料在降低制造成本的同时,利用分散于聚合物中MWNTs的一维电子传输特性及形成的大量界面势垒,加上ZnO半导体纳米线具有的较高载流子密度与迁移率,提高了复合热电材料中电子的输运特性,增加了材料对声子的散射强度.测试发现,在一定的温度梯度下,随着MWNTs添加质量百分比的增加,热电材料的温差电动势和电导率也随之增加,但其Seebeck系数变化量不大.研究表明,这种热电材料有望替代采用p型与n型SWNTs构建的SWNTs/PVDF复合热电材料.研究结果对开发超轻、无毒、廉价、可应用于各种微纳电子领域的新型电源具有重要的参考价值.     

碳纳米管用作超级电容器电极材料

碳纳米管由于具有化学稳定性好、比表面积大、导电性好和密度小等优点，是很有前景的超级电容器电极材料。本文介绍了碳纳米管用作超级电容器电极材料的研究现状，总结了单纯碳纳米管电极材料和碳纳米管复合物电极材料的特点与性能，并探讨了今后碳纳米管电极材料的发展方向。     

Green synthesis of polymer nanofibers and their composites as flame‐retardant materials for polymer nanocomposites

Polyaniline nanofibers and their composites with carbon nanotubes were developed as an effective flame‐retardant material using a facile green method. Polyaniline nanofibers were used as a smart flame‐retardant for acrylonitrile–butadiene–styrene polymer. The polyaniline nanofibers were dispersed in polymer matrix forming well‐dispersed polymer nanocomposites. Effect of polyaniline nanofiber mass ratio on the polymer nanocomposite properties was studied. Polyaniline nanofiber composites with carbon nanotubes were also dispersed in polymer matrix. The thermal stability and flammability properties of the polymer nanocomposites were investigated. The rate of burning of polymer nanocomposites achieved 82.5% reduction (7.32 mm/min) compared with virgin polymer (42.5 mm/min). The reduction in peak heat release rate and total heat release of the polymer nanocomposites containing nanofibers achieved 74 and 34%, respectively. Interestingly, the average mass loss rate was significantly reduced by 58% and the emission of carbon monoxide and carbon dioxide gases were suppressed by 20 and 47%, respectively. The effect of polyaniline nanofibers composites on the flammability of polymer nanocomposites was also studied. Polyaniline nanofibers and their composites were characterized using Fourier transform infrared spectroscopy and transmission and scanning electron microscopy. The dispersion of polyaniline nanofibers in polymer nanocomposites was characterized using transmission electron microscopy. The different polymer nanocomposites were characterized using thermogravimetric analysis, UL94 flame chamber, and cone calorimeter tests. Copyright © 2016 John Wiley & Sons, Ltd.     

Polyaniline/Silver Nanoparticle-Doped Multiwalled Carbon Nanotube Composites

A simple method was used to synthesize the hybrid nanocomposites consisting of the functionalized multiwalled carbon nanotube composites (MWCNTs) with the polyaniline incorporated silver nanoparticles (a-MWCNT/PANI-Ag) through an emulsion polymerization at room temperature in order to enhance the electrical conductivity of polyaniline. The electrical conductivity of the composite with the incorporated Ag nanoparticles was 5% higher than the same weight percent for the composite without Ag nanoparticles, and the thermal stability was dramatically increased from 54% for the composite (a-MWCNT/PANI) to 69% through the incorporation of the Ag nanoparticles at 830°C. Additionally, the advantages of the Ag nanoparticles, including the improved electrical and thermal properties without damage to the polyaniline structure, were confirmed using FTIR and Raman spectroscopy.     

The composites of polyaniline with multiwall carbon nanotubes: Preparation,electrochemical properties,and conductivity

Composite materials based on the multiwall nanotubes (content in the material from 1 to 65 wt %) and polyaniline are prepared and characterized. The composite materials are prepared by four methods: chemical synthesis, electrochemical synthesis, mixing of dry components, and mixing of solutions with subsequent removal of solvent. The results of calculations of the specific capacity of the composite materials, as well as their conductivity, stability, and behavior under the conditions of charging-discharging point out to their applicability in devices for the energy storage. The range of critical changes in the values of specific capacity and conductivity falls into the interval of the multiwall nanotubes content in the composite from 5 to 25 wt %. The composite materials preparation methods used in this work enable one to choose an appropriate composite preparation method reasoning from the final purpose of its application (obtaining of high capacity or conductivity). The carbon nanotubes, the body of the composite, with their stable electronic conduction, can sustain the composite’s electrical conductivity at reasonable level irrespective of the properties of the second component (polyaniline) in the case in question.     

Responses and thermal conductivity measurements of multi-wall carbon nanotube (MWNT)/epoxy composites

In the present study, the MWNT/epoxy composites are prepared with three weight percentages (0.0, 0.3, and 0.5%) of multiwall carbon nanotube (MWNT). The temporal response of multi-wall carbon nanotube (MWNT)/epoxy composite with different wt% of multi-wall carbon nanotube (MWNT) is measured by experiment. Also, a cavity-type measuring system is designed to experimentally measure the surface temperatures and obtain the thermal conductivity of these composites at different heating rates. It is found that the responses of the 0.3 and 0.5% weight percentage of multi-wall carbon nanotube (MWNT)/epoxy composites are found to be about 25 and 47.8%, respectively, faster than that of the pure epoxy resin. Both the responding characteristics and the variation trends of the measured surface temperatures of these composites can be well predicted by the lumped-heat capacity model. Besides, the higher the weight percentage (wt%) of multi-wall carbon nanotube (MWNT) in the composite, the larger is the thermal conductivity. Relative to the pure epoxy, the thermal conductivities for the composites with 0.3 and 0.5% of multi-wall carbon nanotube (MWNT) increase by 15.9 and 44.9%, respectively. For the weight percentages studied, the thermal conductivity of these composites is found to increase mildly at low heating rates; however, it remains nearly constant at high heating rates.     

磺化碳纳米管改性聚苯胺复合材料的合成与超级电容特性

运用重氮化技术制备了水溶性磺化碳纳米管,在此基础上,以不同直径的磺化碳纳米管(1～2 nm,<8 nm,10～20 nm,30～50 nm)为载体,采用原位氧化聚合方法合成了一系列磺化碳纳米管改性聚苯胺复合材料.红外和紫外-可见光谱分析表明,聚苯胺与磺化碳纳米管之间存在π-π相互作用,并形成了电荷转移复合物;且随着碳纳...     

Effect of impurity on electronic properties of carbon nanotubes

We have studied the effect of impurity on electronic properties of single-walled carbon nanotubes using Density Functional Theory. Electronic band structures and density of states of (4, 4) and (7, 0) carbon nanotubes in the presence of different amount of B and N impurities were calculated. It was found that these impurities have significant effect on the conductivity of carbon nanotubes. The metallic (4, 4) nanotube remains to be metallic after doping with B and N. The electronic properties of small gap semiconducting (7, 0) tube can extensively change in the presence of impurity. Our results indicate that B-doped and N-doped (7, 0) carbon nanotubes can be p-type and n-type semiconductors, respectively.