量子约束混合相纳米晶/非晶硅的带隙和载流子输运工程

T. Guan, Grant Klafehn, C. Kendrick, San Theingi, Idemudia Airuoyo, M. Lusk, P. Stradins, Craig J Taylor, R. Collins
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引用次数: 1

摘要

将单独沉积区制备的纳米硅粒子(SiNPs)与氢化非晶硅(a- si:H)同时沉积,制备了带隙高于体硅的混合相纳米晶/非晶硅(nc/a- si:H)薄膜。由于两个沉积相是很好的解耦,每个组件的优化参数可以应用于生长过程。光致发光光谱(PL)表明,嵌入的SiNPs足够小,可以表现出量子约束效应。在混合相上的低温PL测量显示了一个主要的发射特征,这与被a- si:H包围的SiNPs有关。此外,我们比较了a-Si:H和混合相材料在强激光照射下不同时间(最多两小时)的低温PL测量值与时间的关系。嵌入SiNPs的a-Si:H的发光强度比纯a-Si:H的发光强度衰减小得多。我们提出这种光稳定性的改善是因为在a-Si:H矩阵中产生的载流子迅速转移到sinp中并在那里重组,而不是在a-Si:H中重组并产生缺陷态(Staebler-Wronski效应)。
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Bandgap and carrier transport engineering of quantum confined mixed phase nanocrystalline/amorphous silicon
Mixed phase nanocrystalline/amorphous-silicon (nc/a-Si:H) thin films with band-gap higher than bulk silicon are prepared by depositing silicon nanoparticles (SiNPs), prepared in a separate deposition zone, and hydrogenated amorphous silicon (a-Si:H), simultaneously. Since the two deposition phases are well decoupled, optimized parameters for each component can apply to the growth process. Photoluminescence spectroscopy (PL) shows that the embedded SiNPs are small enough to exhibit quantum confinement effects. The low temperature PL measurements on the mixed phase reveal a dominant emission feature, which is associated with SiNPs surrounded by a-Si:H. In addition, we compare time dependent low temperature PL measurements for both a-Si:H and mixed phase material under intensive laser exposure for various times up to two hours. The PL intensity of a-Si:H with embedded SiNPs degrades much less than that of pure a-Si:H. We propose this improvement of photostability occurs because carriers generated in the a-Si:H matrix quickly transfer into SiNPs and recombine there instead of recombining in a-Si:H and creating defect states (Staebler-Wronski Effect).
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