基于择优掺杂取向研究Y掺杂量对ZnTe电子结构和吸收光谱的影响  

作　　者：李昊男 李聪 LI Hao-Nan;LI Cong(School of Physics and Electrical Engineering,Mudanjiang Normal College,Mudanjiang 157000,China)

机构地区：[1]牡丹江师范学院物理与电子工程学院,牡丹江157000

出　　处：《原子与分子物理学报》2024年第6期139-146,共8页Journal of Atomic and Molecular Physics

基　　金：黑龙江省省属高校基本科研业务费重点项目(1452ZD014);黑龙江省自然科学基金(LH2022A025);牡丹江师范学院国家级课题培育项目(GP2022002)。

摘　　要：Zn Te由于其特有的禁带宽度,光学性质以及可重掺杂等特性,使得众多学者对其进行了系列的相关研究,但关于Y掺杂浓度和掺杂方式对Zn Te性质的影响却鲜有报道.作者采用密度泛函理论框架下的广义梯度近似方法,分别计算了Y在掺杂浓度为1.56at%、3.12at%、4.69at%下Zn Te的几何结构、能带结构、态密度分布、吸收光谱等性质,以及不同掺杂方式对体系的影响.结果表明:在掺杂浓度为3.12at%,掺杂方式不相同时,掺杂原子沿[111]晶向排布的形成能最低,即[111]晶向为择优晶向.当掺杂浓度为4.69at%时,择优晶面为(111)面.若要实现更高浓度的Y掺杂,沿(111)晶面掺杂更容易实现.对于实验而言,更高浓度的Y掺杂,掺杂原子在Zn Te体系中更容易沿(111)晶面进行集中排列. Y掺杂Zn Te后,体系的禁带宽度变大,吸收光谱发生蓝移,对可见光的吸收强度减小.在浓度为3.12at%时禁带宽度最大,蓝移现象最明显,吸收强度最小. Y掺杂后体系变为n型半导体,可以使用这种掺杂方式制作P-N结二极管.ZnTe has been subjected to a series of related studies by many scholars due to its unique forbidden band width, optical properties and heavy doping. There is no reported on the effects of Y doping concentration and doping method on the properties of ZnTe. The authors used the generalized gradient approximation method under the framework of density function theory to calculate the geometries, band structures, density of states distributions, absorption spectra and other properties of ZnTe at doping concentrations of 1.56at%, 3.12at% and 4.69at%. And the effects of different doping methods on the system was also researched. The results show that at a doping concentration of 3.12at% with different doping methods, the formation energy of the doped atoms along the [111] crystal orientation is the lowest, i.e. , the [111] crystal orientation is the preferred crystal orientation. When the doping concentration is 4.69at%, the preferred crystallographic plane is the (111 ) plane. To achieve a higher concentration of Y doping, doping along the (111 ) crystal plane is more easily achieved. For experimental purposes, higher concentration of Y doping makes it easier to concentrate the dopant atoms in the ZnTe system along the (111 ) crystal plane. The Y doping results in a larger forbidden band width of ZnTe, a blue shift in the absorption spectrum and a reduction in the intensity of absorption of visible light. When the concentration is 3.12at%, the band gap width is the largest, the blue shift is the most obvious, and the absorption intensity is the smallest.The system becomes a n-type semiconductor after Y doping, and P-N junction diodes can be made using this doping method.

关 键 词：Y掺杂ZnTe 掺杂浓度与方式 第一性原理 电子结构 光电性质 

分 类 号：O65[理学—分析化学]