导电高分子

  • 网络conducting polymer;conductive polymer;pedot
导电高分子导电高分子
  1. 正温系数(Positivetemperaturecoefficient)导电高分子材料(PTC材料)在工业中得到了广泛的应用。

    Conducting polymers with positive temperature coefficient are extensively used in industrial sectors today .

  2. 几种导电高分子的Raman光谱研究

    Raman Studies on Several Conducting Polymers

  3. C(60)掺杂型导电高分子的研究

    Study on C_ ( 60 ) - doped Conductive Polymers

  4. 本文综述了近年来C(60)掺杂型导电高分子的研究进展。

    Recent progress about C ( 60 ) - doped conductive polymers has been reviewed .

  5. 具有PTC效应的导电高分子复合材料的研究及应用

    Studies and Applications on Conductive Polymer Composites Having PTC Effect

  6. 通过实例,结合光谱的研究,阐述了C(60)与被掺杂的导电高分子之间存在3种相互作用方式。

    It is concluded that there are three kinds of interaction forms between C ( 60 ) and conductive polymers through investigation on the changes in their various spectra .

  7. 采用溶液聚合与乳液聚合两种方法分别合成了导电高分子材料聚苯胺(PAn),并对其性能进行了比较研究。

    The conductive material , polyaniline ( PAn ), is polymerized by means of emulsion and aqueous solution respectively .

  8. 在众多导电高分子材料中,聚苯胺(PAn)是被研究最广泛并最有实际应用前景的导电聚合物之一。

    Polyaniline ( PAn ) is one of the most intensively investigated and prospective in application among conductive polymers .

  9. 对高分子聚合物ABS进行纳米碳黑填充改性及其导电高分子材料的导电机理进行了研究。

    The modification of acrylonitrile butadiene styrene with nano-carbon black additive ( CB / ABS ) and their conduction mechanism are studied .

  10. 聚苯胺(PANI)是研究最为广泛的导电高分子材料之一。

    Polyaniline ( PANI ) is one of the most intensively researched conductive polymer materials .

  11. PPV导电高分子膜可充电电池的特性研究

    Research of the Property of Rechargeable PPV Batteries

  12. 纳米TiO2-V2O5复合聚苯胺导电高分子材料的制备

    Preparation of TiO_2-V_2O_5 / PANI Nanometer Conducting Composite Polymers Material

  13. 基于Maxwell理论和平均极化理论,建立了导电高分子复合材料的有效电导率模型。

    Based on Maxwell theory and average polarization theory , a new model for effective electric conductivity of conductive polymer composite was established .

  14. III型聚合物超电容器所用的导电高分子主要包括聚噻吩衍生物类,如:聚-3-(4-氟苯基)噻吩、聚二噻吩[3,4-b;3,4-d]噻吩,聚苯胺类等。

    The major conducting polymers used in Type III supercapacitors are poly ( 3-phenylthiophene ) derivatives , polydithieno [ 3,4-B : 3,4-D ] thiophene and polyaniline derivatives et al .

  15. 聚对苯乙炔(PPV)不仅是一种导电高分子材料,同时也是一种性能良好的电致发光材料。

    Poly-phenylene vinylene ( PPV ) is not only a kind of conducting material but a fine kind of electroluminescent material .

  16. 聚苯胺(PAn)是最早发现的导电高分子材料之一,由于其环境稳定性好、合成方法简单,单体价廉易得等优点而受到了广泛的关注。

    Polyaniline ( PAn ), one of the oldest conductive polymer , is under extensive study even today because of its high environmental stability , low cost , and simple synthesizing procedures .

  17. 研究了EPDM/LLDPE/CB复合型导电高分子材料电阻率的温度依赖性,炭黑含量的依赖性及热功率特性。

    The dependence of resistivity on temperature and carbon black content , and power characteristics of EPDM / LLDPE / CB conductive polymer composite were studied .

  18. 因此,掺杂剂的引入是一种增强有机导电高分子材料导电性的重要方法,而我们研究的KCl掺杂聚苯甲亚胺,在合适的掺杂浓度下,是一种潜在的导电高分子材料。

    Consequently , the introduction of dopant is one of the principle methods in an attempt to enhance the electrical conductivity of organic conducting materials .

  19. 如果根据材料的两种实际结构,考虑两种耦合的重要性。对于导电高分子,非局域电声耦合比较重要;对于DNA分子来说,局域电声耦合占主要地位。

    If we consider the actual structure of the materials and the importance of the two kinds of el-ph coupling , the nonlocal electron-phonon interaction is more important for the conducting polymers . For DNA molecules , the local electron-phonon interaction dominated .

  20. 聚苯胺(PANI)是一个综合性能优良的导电高分子材料,特别是它独特的掺杂机制和优异电化学性能,使其在防腐蚀领域中得到很好应用。

    Due to the unique doping mechanism and outstanding electrochemical properties , one of the applications of polyaniline ( PANI ) is the corrosion protection of metals .

  21. 聚苯胺(PANI)因其原料便宜,合成简单,稳定性及抗氧化性能良好,成为最具有商业价值的导电高分子材料之一。

    Polyaniline ( PANI ) is one of the most commercially valuable conducting polymers duo to its low cost , ease of synthesis , excellent environmental stability .

  22. 炭黑(CB)填充导电高分子复合材料已经在抗静电、电磁波屏蔽、自控温加热带以及各种传感器中获得广泛应用。

    Carbon black ( CB ) - filled conductive polymer composites have been widely used in anti-static , electromagnetic shielding , heating tapes with automatic temperature control and various sensors .

  23. 自掺杂导电高分子中取代基对主链电荷分布的影响导电高分子膜包覆YBa2Cu3O7超导体抗环境作用的研究

    Influence of Substituent of Self-doping Conductive Polymer on Charge Distribution in Polymer Chain Conductive Polymer Encapsulation of YBa_2Cu_3O7 for Protection Against Reactive Environments

  24. 采用4种不同方法合成了导电高分子聚(2,5-二甲氧基对苯乙炔)(PPV),并对性能进行了研究。

    Conductive polymers of poly ( 2,5 dimethoxy p phenylene vinylene ) were synthesized by four different methods , and their photoluminescent and conductive properties were studied .

  25. 导电高分子能带的Wannier函数方法

    Wannier-Function Method of Energy Bands for Conducting Polymers

  26. 综述了聚吡咯(PPY)、聚苯胺和聚(3,4–次乙二氧基噻吩)(PEDOT)等导电高分子材料在铝固体电解电容器中应用的最新研究情况。

    Recent development in solid aluminium electrolytic capacitors with conducting polymers , such as polypyrrole , polyaniline and poly ( 3,4-ethylenedioxythiophene ) is reviewed .

  27. 在导电高分子材料中,具有共轭双键的聚吡咯(PPy),与其它导电高分子相比具有合成简便、易成膜、抗氧化性能良好、电导率较高等优点而日益受到人们的关注。

    Compared to other conducting polymer , PPy with conjugated double bonds has gained much attention due to its ease of polymerization , conveniency of making films , good oxidation resistance and high conductivity .

  28. 提高PEG链段长度和含量,PAn-g-PEG能形成稳定的水溶性分散体系,并能浇注成柔韧平整的导电高分子自支撑膜。

    A soft and smooth conducting polymeric film can be directly obtained by casting the stable aqueous dispersion of PAn-g-PEG , which becomes water-soluble when the PEG segments length or content are increased .

  29. 聚苯胺(PANI)因其单体价格便宜、制备条件简单以及较高的电导率和良好的环境稳定性,而成为倍受青睐的导电高分子材料。

    Polyaniline ( PANI ) is one of the most investigated conducting polymers ( CP ) . It has been frequently studied due to its low cost , ease in preparation , good environmental stabilities , and high conductivity .

  30. 聚苯胺(PANI)因其原料易得、合成方法简单、电导率较高且可调、环境稳定性好以及独特的化学和电化学性能,成为最有应用前景的导电高分子材料。

    Methods of Improving Conductivity of Conductive Polymers Polyaniline ( PANI ) is one of the most promising conductive polymers due to its lower cost , higher and tunable conductivity , environmental stability and unique chemical and electrochemical properties .