量子阱
超晶格
材料科学
合金
凝聚态物理
电子迁移率
三元运算
散射
限制
自旋电子学
量子计算机
三元合金
量子
光电子学
物理
冶金
计算机科学
量子力学
铁磁性
激光器
工程类
程序设计语言
机械工程
作者
Jason T. Dong,Y Gul,Aaron N. Engel,Teun A. J. van Schijndel,Connor P. Dempsey,M. Pepper,C. J. Palmstrøm
标识
DOI:10.1103/physrevmaterials.8.064601
摘要
High In content InGaAs quantum wells (In $\ensuremath{\ge}$ 75%) are potentially useful for topological quantum computing and spintronics applications. In high-mobility InGaAs quantum wells, alloy disorder scattering is a limiting factor. In this paper, we demonstrate that by growing the InGaAs quantum wells as a digital alloy, or a short period superlattice, we can reduce the alloy disorder scattering within the quantum well and increase the peak 2 K electron mobility to $545\phantom{\rule{0.16em}{0ex}}000 {\mathrm{cm}}^{2}$/Vs, which is the highest reported mobility for high-In content InGaAs quantum wells to the best of the authors' knowledge. Our results demonstrate that the digital alloy approach can be used to increase the mobility of quantum wells in random alloy ternary materials.
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