二氧化硅功能化:如何影响直流条件下纳米介电体的空间电荷积累?

Amirhossein Mahtabani, I. Rytöluoto, R. Anyszka, Eetta Saarimäki, Xiaozhen He, K. Lahti, M. Paajanen, W. Dierkes, A. Blume
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引用次数: 0

摘要

在聚丙烯(PP)/乙烯-辛烯共聚物(EOC) /二氧化硅纳米电介质中研究了极性氨基硅烷对二氧化硅纳米粒子的功能化及其对高压直流电(DC)下空间电荷积累的影响。通过改变改性反应条件,改变了沉积层的接枝密度和形貌,从而改变了填料-聚合物的界面性能。然后研究了这种变化对高直流场下空间电荷积累的影响,这是高压直流电缆绝缘系统最重要的调谐特性之一。首先通过热重分析(TGA)和傅里叶变换红外光谱(FTIR)证实了二氧化硅表面的化学修饰。采用差示扫描量热法(DSC)研究了纳米工程界面面积对纳米复合材料成核和晶体形成的影响。采用热激去极化电流(TSDC)方法研究了胺类官能团对该绝缘体系中载流子捕获和输运的影响。结果表明,二氧化硅表面的胺官能团会在填料-聚合物界面处诱发深阱态,阻碍空间电荷的进一步注入。在一定的修饰条件下,氨基硅烷可以在二氧化硅表面形成“岛状”结构。这些岛既可以促进成核,在填料-聚合物界面诱导转晶,又有助于诱导深阱,从而减少纳米介电介质中的空间电荷积累。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Silica Functionalization: How Does it Affect Space Charge Accumulation in Nanodielectrics Under DC?
Functionalization of silica nanoparticles with polar aminosilane and its effect on space charge accumulation under high voltage direct current (DC) was studied in polypropylene (PP)/ Ethylene-Octene Copolymer (EOC) /silica nanodielectrics. The modification reaction conditions were varied in order to alter the deposited layer grafting density and morphology, and hence, the filler-polymer interfacial properties. The effect of this alteration was then studied on the space charge accumulation under a high DC field as one of the most important properties to tune for HVDC cable insulation systems. The chemical modification of the silica surface was first confirmed via Thermogravimetric Analysis (TGA) and Fourier Transform IR Spectroscopy (FTIR). Differential Scanning Calorimetry (DSC) was performed on the nanocomposites to study the effect of the nano-engineered interfacial areas on nucleation and crystal formation. The effect of the amine functional groups on the charge carrier trapping and transport in this insulation system was studied via Thermally Stimulated Depolarization Current (TSDC) method.It was argued that the amine functionality on the silica surface can induce deep trap states at the filler-polymer interfaces, and hinder further injection of the space charge. Under certain modification conditions, the aminosilane can form “island-like” structures on the silica surface. These islands can both facilitate nucleation, inducing transcrystallization at the filler-polymer interface, and further contribute to the induction of deep traps which result in reduction of space charge accumulation in the nanodielectric.
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