摘要
AgSnO_(2)触头材料由于优异的性能成为代替AgCdO的电接触材料之一,但由于SnO_(2)导电性能较差以及硬度大,会使材料变脆,容易形成裂纹,降低了AgSnO_(2)触头的使用寿命。采用基于密度泛函理论的第一性原理方法,研究了稀土元素Ce和C单掺杂以及共掺杂SnO_(2)的导电性能和力学性质。通过超晶胞结构优化后的能量计算,得到了超晶胞的晶格常数、掺杂形成能、能带结构、态密度、弹性常数和德拜温度。结果表明:通过掺杂后的带隙值减小,增加了杂化轨道,能够提高SnO_(2)的导电性能以及改善SnO_(2)的脆韧性,从而改善AgSnO_(2)触头的成型和使用寿命。相对于Ce、C单掺杂,Ce-C共掺杂时的电子有效质量减小,并且带隙宽度变窄,Ce-C共掺杂SnO_(2)的导电性能更好,硬度的改善更大。
AgSnO_(2)contact material has become one of the electrical contact materials to replace AgCdO because of its excellent performance.However,since the poor electrical conductivity and high hardness of SnO_(2),the material will become brittle and easy to form cracks,which reduces service life of AgSnO_(2)contacts.In this paper,the first-principles method based on density functional theory is adopted to study the electrical conductivity and mechanical properties of the rare earth elements Ce and C single-doped and co-doped SnO_(2).Through the energy calculation after the supercell structure is optimized,the lattice constant,doping formation energy,band structure,density of state,elastic constant and Debye temperature of the supercell are obtained.The results show that the band gap value of doped tin dioxide is reduced and the hybrid orbit increased,the conductivity of SnO_(2)and the brittleness and toughness of SnO_(2)can be improved,thereby improving the forming and service life of AgSnO_(2)contacts.Compared with Ce and C single doping,the effective electronic mass of Ce-C co-doping is reduced,and the band gap width is narrowed.Ce-C co-doped SnO_(2)has better conductivity and greater improvement in hardness.
作者
阳建宇
王景芹
朱艳彩
张广智
胡德霖
黄光临
YANG Jianyu;WANG Jingqin;ZHU Yancai;ZHANG Guangzhi;HU Delin;HUANG Guanglin(State Key Laboratory of Electrical Equipment Reliability and Intelligentization,Hebei University of Technology,Tianjin 300130,China;Shanghai Liangxin Electric Co.,Ltd.,Shanghai 200137,China;Suzhou Electrical Apparatus Research Institute Co.,Ltd.,Suzhou 215104,China;Wenzhou Juxing Technology Co.,Ltd.,Wenzhou 325062,China)
出处
《有色金属工程》
CAS
北大核心
2021年第8期1-8,共8页
Nonferrous Metals Engineering
基金
国家自然科学基金资助项目(51777057)。
关键词
第一性原理
Ce-C共掺杂
导电性能
力学性质
first-principles
Ce-C co-doping
electrical conductivity
mechanical properties
