锗量子点是由SiGe合金氧化形成的

贵州科学 Pub Date : 2006-05-20 DOI:10.7498/aps.55.2488
L. Shi-rong, Huang Wei-qi, Qin Zhao-Jian
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引用次数: 4

摘要

本文报道了Si 1-x Ge x合金(x=0.05, 0.15和0.25)的氧化行为。在Si 1-x Ge x衬底氧化形成的锗量子点的PL光谱中,在高氧化温度(800℃~ 1000℃)下,锗纳米粒子的直径分布(锗团簇直径为3nm ~ 4nm)产生了550nm ~ 720nm的发射带;在低氧化温度(400℃~ 600℃)下,激光束辐射有650 ~ 900nm的发光带,可能来自直径为4nm ~ 5nm的锗团簇。可以清楚地看到,沿发射波段在572nm、620nm、671nm、724nm、769nm、810nm和861nm处存在多个峰,这与锗团簇直径分别为3.32nm、3.54nm、3.76nm、3.98nm、4.17nm、4.35nm和4.62nm时的量子约束效应有关。MC方法的模拟结果表明,在上述条件下,上述直径的锗团簇更加稳定。建立了量子约束模型,并提出了用超高频光谱法计算和量子约束分析来解释PL光谱的方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Germanium quantum dots formed by oxidation of SiGe alloys
We report the investigation on the oxidation behavior of Si 1-x Ge x alloys (x=0.05, 0.15, and 0.25). In the PL spectra of Germanium quantum dots formed by the oxidation of Si 1-x Ge x substrate, at high oxidation temperature (800℃—1000℃) an emission band from 550nm to 720nm would originate from the diameter distribution of germanium nanoparticles (Ge clusters diameter: 3nm—4nm); and at low oxidation temperature (400℃—600℃) with Laser beam radiation, there is an emission band from 650nm to 900nm which may have come from the germanium clusters (diameter: 4nm—5nm). It is clearly seen that there are several peaks at 572nm, 620nm, 671nm, 724nm, 769nm, 810nm and 861nm wavelengths along the emission band, which are correlated to the quantum confinement effect with 3.32nm, 3.54nm, 3.76nm, 3.98nm, 4.17nm, 4.35nm and 4.62nm diameters of the germanium clusters, respectively. The simulation result with MC method demonstrates that the germanium clusters of the above diameters are more stable under the above conditions. A quantum confinement model has been set up, and calculations with the UHFR method and the quantum confinement analysis have been proposed to explain the PL spectra.
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