Charge Transport Characteristics of ZnO/Polyimide Nanocomposite Under Vacuum DC flashover

Bo Zhang, Jiang Wu, Xiaoquan Zheng
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引用次数: 2

Abstract

Polyimide is a commonly used polymer dielectric material on spacecraft. The vacuum and radiation environment can easily lead to the accumulation of static charge on the spacecraft and trigger the surface discharge. Therefore, improving the surface DC flashover voltage of the dielectric in the space environment is crucial to improve the reliability of the spacecraft. In this paper, ZnO/PI nanocomposite was prepared to improve the flashover voltage. The electrical performance test including the relative permittivity, surface and bulk resistivity of the specimen was tested. The thermally stimulated depolarizing current method was used to analyze the trap parameters. The results show that the flashover voltage of PI is enhanced by nano ZnO, among which the flashover voltage increases the most at 3wt% ZnO content. Further analysis shows that the surface flashover intensity depends on the trap density, conductivity and methods of charge transportation and accumulation. The higher the trap density and higher electrical conductivity in the ohmic region, the lower the charge accumulated and the higher the flashover.
ZnO/聚酰亚胺纳米复合材料在真空直流闪络下的电荷输运特性
聚酰亚胺是航天器上常用的高分子介质材料。真空和辐射环境容易导致航天器上静电荷的积累并引发表面放电。因此,提高空间环境下电介质的表面直流闪络电压对提高航天器的可靠性至关重要。本文制备了ZnO/PI纳米复合材料来提高闪络电压。电性能测试包括试样的相对介电常数、表面电阻率和体电阻率。采用热激去极化电流法对陷阱参数进行了分析。结果表明:纳米ZnO能提高PI的闪络电压,其中ZnO含量为3wt%时,闪络电压升高幅度最大;进一步分析表明,表面闪络强度与陷阱密度、电导率以及电荷输运和积聚方式有关。陷阱密度越大,欧姆区电导率越高,电荷积累越少,闪络越强。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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