Strained Si1-xGex/Si Dots and Wires Grown by Selective Epitaxy

L. Vescan, R. Loo, A. Souifi, C. Dieker, S. Wickenhauser
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引用次数: 1

Abstract

Selective epitaxial growth of Si 1-x Ge x was studied with the aim to fabricate quantum wires and dots. The selective deposition was performed by low pressure chemical vapor deposition with dichlorosilane and germane as precursors, at 0.1 Torr and 700°C in a radiation heated, cold wall, high vacuum, quartz reactor. Dislocation free strained dots and wires could be grown much thicker than the critical thickness for unpatterned area, because the critical thickness by formation of misfit dislocations increases when the window dimension is reduced. For x up to 20% it was found that for 10x10 μm 2 dots the critical thickness increases by more than 4 times. The tendency of facet formation was exploited to realize laterally confined multiple quantum well dots and wires with sizes down to 50 nm. Besides the emission from the (100) quantum well layers excitonic emissions from quantum well layers from flat {110} facets and from islands in the (100) and {311} facets were detected. All dots and wires luminesce stronly down to the lowest achieved dimension of 50 nm, the integral intensity exceeding that from the substrate.
选择性外延生长的应变Si1-xGex/Si点和线
以制备量子线和量子点为目的,研究了Si -x - Ge -x的选择性外延生长。在辐射加热、冷壁、高真空石英反应器中,以二氯硅烷和日耳曼为前驱体,在700°C、0.1 Torr温度下,采用低压化学气相沉积法进行选择性沉积。由于错配位错形成的临界厚度随着窗口尺寸的减小而增大,无位错的应变点和应变线可以生长得比无图案区域的临界厚度大得多。当x达到20%时,发现对于10x10 μm 2的点,临界厚度增加了4倍以上。利用晶面形成的趋势,实现了横向受限的多量子阱点和尺寸小至50 nm的量子阱线。除了从(100)量子阱层发射外,还检测到从平面{110}面的量子阱层和从(100)和{311}面的岛状量子阱层的激子发射。所有点和线的发光强度都达到了50nm的最低尺寸,整体强度超过了衬底的发光强度。
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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