GaAs/AlAs quantum wells for selective terahertz sensing: study by differential surface photovoltage spectroscopy

International Conference on Advanced Optical Materials and Devices Pub Date : 2006-02-19 DOI:10.1117/12.726400

J. Kavaliauskas, B. Čechavičius, G. Krivaitė, D. Seliuta, G. Valušis, B. Sherliker, M. Halsall, P. Harrison, S. Khanna, E. Linfield

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Abstract

We have studied interband optical transitions, electronic structure and structural quality of p-type (Be) and n-type (Si) &dgr;- doped GaAs/AlAs MQWs designed for selective THz sensing applying differential surface photovoltage (DSPV) spectroscopy. Sharp derivative-like features associated with excitonic optical transitions in GaAs/AlAs MQWs have been observed in the spectra at 300 K and 90 K temperature. The energies and line broadening parameters for a large number of QW related excitonic transitions were determined from the line-shape analysis of the DSPV spectra. The spectroscopic data of transition energies were found to be in a good agreement with calculations within the envelope function approximation which took into account the nonparabolicity of energy bands. Analysis of the dependence of the exciton linewidth broadening on the quantum subband number allowed evaluate line-broadening mechanisms and interface roughness in the MQW structures. It was determined that doping with Si broadens more effectively the optical spectra lines in comparison with the structures of the same design doped with Be.

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选择性太赫兹传感的GaAs/AlAs量子阱:差分表面光电压谱的研究

我们研究了p型(Be)和n型(Si) &dgr掺杂的GaAs/AlAs MQWs的带间光学跃迁、电子结构和结构质量，这些MQWs是应用差分表面光电压(DSPV)光谱设计用于选择性太赫兹传感的。在300 K和90 K温度下的光谱中，观察到GaAs/AlAs MQWs中与激子光学跃迁相关的尖锐导数特征。通过对DSPV光谱的线形分析，确定了大量量子w相关激子跃迁的能量和谱线展宽参数。跃迁能的光谱数据与考虑能带非抛物性的包络函数近似的计算结果很好地吻合。通过分析激子线宽展宽与量子子带数的关系，可以评估MQW结构中的线宽展宽机制和界面粗糙度。结果表明，与同样设计的结构相比，掺Si能更有效地拓宽光谱线。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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International Conference on Advanced Optical Materials and Devices

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