有机半导体材料

  • 网络organic semiconductor material;Organic semiconductor
有机半导体材料有机半导体材料
  1. 到目前为止,这一模型能够比较好地解释有机半导体材料及其器件的J-V特性。但是,我们注意到至今没有文献研究和讨论这些理论模型的数值模拟计算方法。

    By now , this model can explain J-V characteristics of organic semiconductor material and device excellently . However , we notice that there is no literature which researches or discusses numerical simulation and numerical calculation method of mobility model and J-V model .

  2. 有机半导体材料以其在低价、柔性、质轻等方面的独特优势,已经在众多下一代半导体技术应用中脱颖而出。

    Organic semiconductor material , known for its unique advantages of low-cost , lightweight and flexibility , has stood out among next-generation semiconductor technologies .

  3. 有机场效应晶体管(OrganicFieldEffectTransistors,OFETs)是以有机半导体材料作为有源层的晶体管器件。

    Organic field-effect transistors ( OFETs ) are the transistors using organic semiconductive materials as active layers .

  4. 表面光电压谱(SPS)在有机半导体材料研究中的应用

    The application of the surface photovoltage spectroscope in the organic semiconductor

  5. PAC及其复合物电荷密度的影响因素分析盘状液晶有较高的载流子迁移速率,作为有机半导体材料有广泛的应用前景。

    Application of High Charge Density PAC in Neutral Papermaking Discotic liquid crystals possess high charge carrier mobility and show huge potential application as organic electronic materials .

  6. 本文总结了近几年有关探索POSS聚合物结构与性能之间关系的研究进展,并重点综述了POSS在有机半导体材料领域的应用。

    This review is intended to cover the more recent advances in both structure-property relationships of POSS-containing polymers and the applications of POSS in organic semiconductors .

  7. 含POSS聚合物的优异性能近期引起了人们的广泛兴趣,例如在耐热阻燃、耐磨损、提高与材料相容性、增强有机半导体材料的发光效率等领域有着大量的报道。

    Recently , POSS containing polymers have attracted considerable research interest due to their versatile applications in heat resistance , flame retardance , abrasion resistance , solubility enhancement and field of organic semiconductors .

  8. 所制备器件采用有机半导体材料酞菁铜(CuPc)作为敏感层,其结构包括Cu/CuPc/Al三层,器件制备在玻璃基板上面。

    The devices that were fabricated on the glass organic used semiconductor materials copper phthalocyanine ( CuPc ) as the sensitive layer , and the structure consists of Cu / CuPc / Al layers .

  9. 由于有机半导体材料具有来源广泛,分子结构易调整、成膜工艺众多且价格低廉等特点,使得OFET相对无机场效应晶体管具有一定的发展优势。

    As the organic semiconductor materials have many virtues , such as , a wide variety of sources , the molecular structure can be adJusted easily , many film forming process and low cost .

  10. 并推导其载流子迁移率各向异性方程,此方程可以用来有效预测有机半导体材料载流子迁移率极值及其方向,同时可实现基于BTBT设计高性能有机半导体材料。

    The anisotropic function of charge transfer mobility is also derived , which could be used to predict the extreme value and its direction of the mobility and design novel organic semiconductor material with high performance based on BTBT .

  11. 基于芘的蝴蝶型有机半导体材料的合成及场效应性能研究

    Novel butterfly pyrene based organic semiconductors for field effect transistors

  12. 对有机半导体材料的导电类型原理做了详细的研究。

    It studies the operation principle of organic semiconductor electric-types in detail .

  13. 主要取得了以下成果:1、设计并合成了一系列可溶性的有机半导体材料。

    A series of soluble organic semiconductor materials have been designed and synthesized .

  14. 有机半导体材料并五苯薄膜的生长

    Growth for Thin Film Of Organic Semiconductor Pentacene

  15. 有机半导体材料中的电荷转移

    Charge Transfer in Organic Semiconductive Materials

  16. 有机半导体材料特性测量及有机场效应管应用的研究

    Measurement of the Characteristics of Organic Semiconductor Materials and the Study of the Application of Organic Field-Effect Transistors

  17. 盘状液晶有较高的载流子迁移速率,作为有机半导体材料有广泛的应用前景。

    Discotic liquid crystals possess high charge carrier mobility and show huge potential application as organic electronic materials .

  18. 有机半导体材料的研究与器件应用是近年来微电子学和光电子学发展的新领域。

    Organic semiconductors and their device applications have opened up a promising new field of research in microelectronics and optoelectronics .

  19. 本论文主要合成了两类杂化有机半导体材料并研究了其光学和电学性能。

    In this thesis , we synthesized two kinds of hybrid organic semiconductors and studied their optical and electronic properties . 1 .

  20. 氟取代的有机半导体材料在光电性能和固体结构上表现出与未取代的同类材料不同的特征。

    The opto / electronic properties and solid-state structures of fluoro-substituted conjugated organic systems exhibit unique characteristics in comparison with their counterparts .

  21. 梯形共轭有机半导体材料,由于其自身结构所特有的双链连接,赋予了其材料良好的稳定性和增加了的载流子迁移率。

    Ladder conjugated organic semiconductors , with their unique structures connected by two chains , shows good stability and enhanced electron mobility .

  22. 有机半导体材料导电性能介于金属和绝缘体之间。

    The organic semiconductor is an organic material with semiconductor property , which conductive property is between the metal and the insulator .

  23. 利用化学修饰,有机半导体材料的电学性能可以进行调节并作为低耗、大面积电子器件的活性层使用。

    Organic semiconductors can be chemically modified to give desired electronic and processing characteristics as the active material in low-cost , large area electronics .

  24. 概述了有机半导体材料产生激光的特性,介绍了贝尔实验室第一个有机固态电注入型激光器的工作原理。

    The characteristics of the organic semiconducting materials and principle of the first electrically pumped solid state organic laser at the Bell laboratory are outlined .

  25. 针对有机半导体材料的蒸发温度低的特点,设计并制作了低温辐射式加热器。

    Based on the low evaporation temperature of organic semiconductors , a radioactive heater-crucible assembly was developed for vacuum evaporation coating and sputtering coating systems .

  26. 因此,在对有机半导体材料的电学性质进行测量时,必须针对这些不同特点设计合理的测量方案。

    So , we must design a reasonable measure plan for these different characters before we measure the electric property of the organic semiconductor material .

  27. 通过计算发现寻找在势垒区中载流子迁移率比较大的有机半导体材料对实现有效的自旋注入是必要的。

    From the calculation , it was found that the high mobility of the carriers in organic semiconductors will be helpful for the spin injection .

  28. 为了增加对有机半导体材料的认识,本文首先对有机半导体材料进行了简单介绍。

    For increasing the understanding of the organic semiconductor material , a brief introduction of the organic semiconductor material was given in this thesis first .

  29. 有机半导体材料通常可以分为两类:有机小分子(或低聚物)和有机聚合物。人们对有机聚合物的研究最为广泛和深入。

    Organic semiconductors can be broadly classified into two categories : small molecules or oligomers and polymers , in which polymers attract much attention and research .

  30. 用有机半导体材料制备的发光器件具有高效率、高亮度、全彩色、低成本等突出优点,在大屏幕固体平面显示等方面有广阔的应用前景。

    The applications of organic semiconductor as active layers in light-emitting devices offer several prominent advantages such as high efficiency , high brightness and low cost .