环氧基片溅射钛副族氧化物薄膜的脉冲真空闪络特性

无机材料学报, 2008, 23(5): 907-911. doi: 10.3724/SP.J.1077.2008.00907

环氧基片溅射钛副族氧化物薄膜的脉冲真空闪络特性

西安交通大学电力设备电气绝缘国家重点实验室, 西安 710049

关键词：环氧基片 , Ti sub-group , oxide thin films , nanosecond pulse , vacuum flashover

Flashover Characteristic of Ti Sub-group Metal Oxide Thin Films on Epoxy Substrate under Nanosecond Pulse in Vacuum

CHEN Yu , CHENG Yong-Hong , WANG Zeng-Bin , ZHOU Jia-Bin , YIN Wei , WU Kai

Keywords： epoxy substrate , 钛副族 , 氧化物薄膜 , 纳秒脉冲 , 真空闪络

在绝缘材料表面制备半导电性及高导热系数的涂层可以明显提高材料的沿面闪络性能．采用高真空反应磁控溅射方法, 在环氧基片表面溅射TiO₂、ZrO₂、HfO₂薄膜, 使用快脉冲真空闪络实验装置(50ns/600ns, 前沿和半高宽时间), 在真空度5×10^-3Pa时, 研究了上述三种氧化物薄膜的真空闪络特性．实验发现, TiO₂和ZrO₂薄膜以无定形态存在, 表面颗粒未晶化, 而HfO₂薄膜已经晶化．TiO₂薄膜的闪络电压最高, HfO₂薄膜较低．TiO₂和HfO₂随着溅射时间的增加, 镀膜的真空闪络电压有所提高, 而ZrO₂随着溅射时间的增加, 镀膜的真空闪络电压有所下降．结合ANSOFT静电场仿真数据, 分析了薄膜的基本特性对闪络后表面电位分布及闪络电压的影响机制．

Design and manufacture of pulse power equipment greatly depend on the investigation of flashover on dielectric surface in vacuum under pulsed voltage. It is expected that sputtering coating with semiconductivity and high thermal conductivity can apparently improve the surface flashover characteristic of dielectric materials. Three kinds of thin films (TiO₂, ZrO₂ and HfO₂) were sputtered on epoxy substrate using magnetron sputtering in ultrahigh vacuum. Experiments were carried out under high voltage pulse (50ns rise time and 600ns full width at half maximum) in vacuum to study the flashover characteristics of three kinds of oxide films. The experimental results show that the TiO₂, ZrO₂ films sputtered on the epoxy substrate are amorphous as they are not annealed and surface grains are not crystalized, but HfO₂film becomes crystalized. The flashover voltage of TiO₂ film is the highest, the flashover voltage of HfO₂ film is close to the epoxy sample. The effect of puttering time on the flashover voltage is different for different target materials. The vacuum flashover voltage increases with the sputtering time increasing for TiO₂ and HfO₂ films, but decreases for ZrO₂ film. Furthermore, the effects of film properties on flashover performance as well as the distribution of surface charge after flashover are analyzed.

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