Energy dispersion relations for holes in silicon quantum wells and quantum wires

Vladimir Mitin; Nizami Vagidov; Mathieu Luisier; Gerhard Klimeck

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Energy dispersion relations for holes in silicon quantum wells and quantum wires

机译：硅量子阱和量子线中空穴的能量色散关系

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We calculate the energy dispersion relations in Si quantum wells (QW), E(k_(2D)), and quantum wires (QWR), E(k_(1D)), focusing on the regions with negative effective mass (NEM) in the valence band. The existence of such NEM regions is a necessary condition for the current oscillations in ballistic quasineutral plasma in semiconductor structures. The frequency range of such oscillations can be extended to the terahertz region by scaling down the length of structures. Our analysis shows that silicon is a promising material for prospective NEM-based terahertz wave generators, We also found that comparing to Si QWRs, Si QWs are preferable structures for NEM-based generation in the terahertz range.

机译：我们计算了Si量子阱（QW），E（k_（2D））和量子线（QWR），E（k_（1D））中的能量色散关系，着重研究了负有效质量（NEM）的区域价带。这种NEM区域的存在是半导体结构中弹道准中性等离子体中电流振荡的必要条件。通过缩小结构的长度，可以将这种振荡的频率范围扩展到太赫兹区域。我们的分析表明，硅是潜在的基于NEM的太赫兹波发生器的有前途的材料。我们还发现，与Si QWR相比，Si QW是在太赫兹范围内基于NEM的发电的首选结构。

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来源
《Journal of Computational Electronics 》 |2007年第3期| p.227-230| 共4页
作者
Vladimir Mitin; Nizami Vagidov; Mathieu Luisier; Gerhard Klimeck;
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作者单位

University at Buffalo, SUNY, 332D Bonner Hall, Buffalo, NY 14260, USA;

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原文格式 PDF
正文语种 eng
中图分类电工技术 ;
关键词
energy dispersion relations; tight-binding model; negative effective mass; quantum well; quantum wire;

机译：能量色散关系;紧束缚模型;负有效质量;量子阱;量子线;

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Energy dispersion relations for holes in silicon quantum wells and quantum wires

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