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Migration-Enhanced Epitaxial Growth of InAs/GaAs Short-Period Superlattices for THz Generation

材料科学 光电子学 超晶格 光电导性 太赫兹辐射 光电流 分子束外延 电子迁移率 外延 纳米技术 图层(电子)
作者
Ruolin Chen,Xuefei Li,Hao Du,Jianfeng Yan,Chongtao Kong,Guipeng Liu,Guangjun Lu,Xin Zhang,Shuxiang Song,Xinhui Zhang,Linsheng Liu
出处
期刊:Nanomaterials [Multidisciplinary Digital Publishing Institute]
卷期号:14 (3): 294-294 被引量:2
标识
DOI:10.3390/nano14030294
摘要

The low-temperature-grown InGaAs (LT-InGaAs) photoconductive antenna has received great attention for the development of highly compact and integrated cheap THz sources. However, the performance of the LT-InGaAs photoconductive antenna is limited by its low resistivity and mobility. The generated radiated power is much weaker compared to the low-temperature-grown GaAs-based photoconductive antennas. This is mainly caused by the low abundance of excess As in LT-InGaAs with the conventional growth mode, which inevitably gives rise to the formation of As precipitate and alloy scattering after annealing. In this paper, the migration-enhanced molecular beam epitaxy technique is developed to grow high-quality (InAs)m/(GaAs)n short-period superlattices with a sharp interface instead of InGaAs on InP substrate. The improved electron mobility and resistivity at room temperature (RT) are found to be 843 cm2/(V·s) and 1648 ohm/sq, respectively, for the (InAs)m/(GaAs)n short-period superlattice. The band-edge photo-excited carrier lifetime is determined to be ~1.2 ps at RT. The calculated photocurrent intensity, obtained by solving the Maxwell wave equation and the coupled drift–diffusion/Poisson equation using the finite element method, is in good agreement with previously reported results. This work may provide a new approach for the material growth towards high-performance THz photoconductive antennas with high radiation power.
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