研究了Na对新型(Co, Nb)掺杂SnO2压敏材料微观结构和电学性质的影响.当Na2CO3的含量从0增加到1.2mol%时, (Co, Nb)掺杂SnO2压敏电阻的击穿电压从275V/mm增到919V/mm.样品的微观结构分析发现,当Na2CO3的含量从0增加到1.2mol%时,SnO2的晶粒尺寸明显的变小.晶界势垒高度测量揭示,SnO2的晶粒尺寸的迅速减小是压敏电压急剧增高的原因.对Na含量增加引起SnO2晶粒减小的根源进行了解释.掺杂0.4mol% Na2CO3的SnO2压敏电阻非线性系数达28.4,击穿电压为755V/mm,掺杂1.2mol% Na2CO3的SnO2压敏电阻非线性系数为11.5,击穿电压高达919V/mm,它们在中高压保护领域会有很好的应用前景.本文并指出替代Sn的受主离子Na不应处于SnO2晶格中,而是处于间界上,从而进一步解释了压敏电压急剧增高的原因.
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