Meyer-Neldel Rule in Plasma Polythiophene Thin Films

In polymers, the electronic activation energy depends on the fragmentation, crosslinking, dopants, moisture and in general on the structure-environment interaction. This has a special importance in plasma polymers because fragmentation and crosslinking are usually higher than in other polymers. In this work, DC electrical conductivity of polythiophene thin films prepared by plasma (pPTh) was studied using the Meyer-Neldel (MN) rule to calculate the characteristic MN energy and temperature as a function of moisture and metallic dopants. The experimental data for pPTh synthesized in different conditions indicated that EM = 32 meV and TM = 373 K, suggesting a thermally activated conduction mechanism;however, in polymer-metal matrices with metal concentration higher than the percolation threshold, the conduction mechanism is different causing that the MN rule was only partially fulfilled. The congruence of the experimental data with the multiexcitation entropy model is discussed.

聚醚酰亚胺纳米复合电介质电导的Meyer-Neldel补偿特性研究

电动汽车和航空航天等领域对极端高温条件下低能量损耗介电储能设备的需求不断增大,亟须开发耐高温的高性能介电储能材料.聚醚酰亚胺因高击穿强度和优越的热稳定性成为耐高温储能薄膜材料的首选,向其掺入纳米粒子是进一步降低高温损耗的有效途径.电导损耗作为能量损耗的主要形式之一,对其内在机理的研究具有重要的科学价值.为揭示纳米粒子掺杂对复合电介质电导特性的影响机理,以聚醚酰亚胺为基体制备了不同掺杂浓度的聚醚酰亚胺/二氧化硅纳米复合电介质.变温电导测试结果表明掺杂纳米粒子可有效降低电导率.采用空间电荷限制电流模型和跳跃电导模型对聚合物纳米复合电介质的变温电导特性进行分析,发现掺杂含量的改变并未引起聚合物中局域态分布形状的改变,表明纳米复合电介质中界面区和基体的电导特性具有一致性.进一步对聚合物纳米复合电介质电导的温度依赖性进行分析,发现其温度依赖性同时满足Arrhenius方程和Meyer-Neldel补偿规则,表明纳米复合电介质中的陷阱与聚合物基体具有相同的机制.根据有序紧密凝聚界面区模型,纳米粒子的掺入是通过降低界面区分子链的柔顺性使局域态能级加大,导致载流子迁移率降低,宏观上表现为电介质的电导率下降,能量损耗降低.

纳米4-H碳化硅薄膜的掺杂现象

对纳米晶SiC薄膜进行了P和B的掺杂 ,B掺杂效率比P高 ,其暗电导预前因子与激活能遵守Meyer Neldel规则 ,并有反转Meyer Neldel规则出现 .掺杂效率比非晶态碳化硅薄膜高是纳米碳化硅薄膜的特点之一 .非晶态中的隧穿和边界透射对输运有一定贡献 .

固态电解质中锂离子传输机理研究进展

固态电解质在室温下表现出非凡的离子导电性,使其有潜力应用于全固态锂离子电池。开发新的高性能固态电解质需要对锂离子传输机理及其规律进行深入研究。本文论述了近期研究中锂离子传输机理方面的研究进展,包括离子传输理论基础的概述;总结Li_(10)GeP_(2)S_(12)、Li_(7)La_(3)Zr_(2)O_(12)和Li_(1+x)Al_(x)Ti_(2-x)(PO_(4))_(3)固态电解质材料中晶体结构、离子传输和研究进展;阐述锂离子传输中结构特征、传输机理(单离子跳跃传输和多离子协同传输)以及构效关系;总结(反)Meyer-Neldel规则的关键问题和相关电解质材料。最后,展望了给出电解质材料的设计策略和未来机理研究的重点,为无机固态电解质材料的探索提供新的思路和方向。