Skin dominance of the dielectric–electronic–phononic–photonic attribute of nanoscaled silicon

IF 8.2 1区 化学 Q1 CHEMISTRY, PHYSICAL Surface Science Reports Pub Date : 2013-11-01 DOI:10.1016/j.surfrep.2013.10.001
Likun Pan , Shiqing Xu , Xinjuan Liu , Wei Qin , Zhuo Sun , Weitao Zheng , Chang Q. Sun
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引用次数: 22

Abstract

Nanoscaled or porous silicon (p-Si) with and without surface passivation exhibits unusually tunable properties that its parent bulk does never show. Such property tunability amplifies the applicability of Si in the concurrent and upcoming technologies. However, consistent understanding of the fundamental nature of nanoscaled Si remains a high challenge. This article aims to address the recent progress in this regard with focus on reconciling the tunable dielectric, electronic, phononic, and photonic properties of p-Si in terms of skin dominance. We show that the skin-depth bond contraction, local quantum entrapment, and electron localization is responsible for the size-induced property tunability. The shorter and stronger bonds between undercoordinated skin atoms result in the local densification and quantum entrapment of the binding energy and the bonding electrons, which in turn polarizes the dangling bond electrons. Such local entrapment modifies the Hamiltonian and associated properties such as the band gap, core level shift, Stokes shift (electron–phonon interaction), phonon and dielectric relaxation. Therefore, given the known trend of one property change, one is expected to be able to predict the variation of the rest based on the notations of the bond order–length–strength correlation and local bond average approach (BOLS-LBA). Furthermore, skin bond reformation due to Al, Cu, and Ti metallization and O and F passivation adds another freedom to enhance or attenuate the size effect. The developed formulations, spectral analytical methods, and importantly, the established database and knowledge could be of use in engineering p-Si and beyond for desired functions.

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纳米硅介电-电子-声子-光子属性的趋肤优势
纳米级或多孔硅(p-Si)表面钝化和未表面钝化表现出不同寻常的可调谐特性,这是其母体从未表现出来的。这种特性的可调性增强了Si在并发和即将到来的技术中的适用性。然而,对纳米级硅的基本性质的一致理解仍然是一个很大的挑战。本文旨在解决这方面的最新进展,重点是协调可调谐的介电、电子、声子和光子性质的p-Si的皮肤优势。我们证明了深层键收缩、局部量子俘获和电子局域化是导致尺寸诱导性质可调性的原因。欠配位的表皮原子之间更短、更强的键导致结合能和成键电子的局部致密化和量子俘获,这反过来又使悬垂的键电子极化。这种局部俘获改变了哈密顿量和相关性质,如带隙、核心能级位移、斯托克斯位移(电子-声子相互作用)、声子和介电弛豫。因此,给定一个属性变化的已知趋势,人们期望能够基于键序-长度-强度相关的符号和局部键平均方法(BOLS-LBA)来预测其余属性的变化。此外,由于Al, Cu和Ti金属化和O和F钝化导致的皮键重组增加了另一个自由来增强或减弱尺寸效应。开发的配方,光谱分析方法,重要的是,建立的数据库和知识可以在工程p-Si和期望的功能之外使用。
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来源期刊
Surface Science Reports
Surface Science Reports 化学-物理:凝聚态物理
CiteScore
15.90
自引率
2.00%
发文量
9
审稿时长
178 days
期刊介绍: Surface Science Reports is a journal that specializes in invited review papers on experimental and theoretical studies in the physics, chemistry, and pioneering applications of surfaces, interfaces, and nanostructures. The topics covered in the journal aim to contribute to a better understanding of the fundamental phenomena that occur on surfaces and interfaces, as well as the application of this knowledge to the development of materials, processes, and devices. In this journal, the term "surfaces" encompasses all interfaces between solids, liquids, polymers, biomaterials, nanostructures, soft matter, gases, and vacuum. Additionally, the journal includes reviews of experimental techniques and methods used to characterize surfaces and surface processes, such as those based on the interactions of photons, electrons, and ions with surfaces.
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