Atomistic Study of Acoustic Phonon Limited Mobility in Extremely Scaled Si and Ge Films

2018 IEEE International Conference on Electronics, Computing and Communication Technologies (CONECCT) Pub Date : 2018-03-16 DOI:10.1109/CONECCT.2018.8482374

P. Rastogi, S. Bhowmick, A. Agarwal, Y. Chauhan

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引用次数: 2

Abstract

We explore the impact of Silicon (Si) and Germanium (Ge) thickness scaling (from 1 to 5 nm) on their electronic and transport properties using density functional theory. We find that in Ge, the lowest conduction band valley shifts from L in bulk to X in ultrathin slabs, and at 1 nm thickness Ge reduces to a direct band gap semiconductor. On the other hand, Si changes to a direct band-gap semiconductor in the thickness range of 1 to 5 nm, as opposed to its indirect nature in bulk form. We show that the electron-phonon coupling, which is the dominant scattering mechanism in these materials, is found to be very weak in scaled Ge-slabs as compared to Si-slabs. This in combination with drastically reduced longitudinal effective mass in thin Geslabs, leads to very high electron mobility in scaled Ge films, which increases with decreasing thickness. Our reported mobility trend in Ge-slabs is in agreement with the recently reported experimental results. For Si-slabs, we show that 3 nm is the most suitable thickness for future ultrathin Si devices as it has the lowest conduction band deformation potential and highest electron mobility.

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极尺度Si和Ge薄膜中声子有限迁移率的原子学研究

我们利用密度泛函理论探讨了硅(Si)和锗(Ge)厚度缩放(从1到5 nm)对其电子和输运性质的影响。我们发现，在Ge中，超薄板的最低导带谷从体中的L变为X，并且在1 nm厚度处Ge减小为直接带隙半导体。另一方面，硅在1 - 5nm的厚度范围内转变为直接带隙半导体，而不是块状形式的间接性质。我们发现，电子-声子耦合是这些材料中主要的散射机制，与硅板相比，锗板中的电子-声子耦合非常弱。这与薄Geslabs中纵向有效质量的急剧减少相结合，导致缩放后的Ge薄膜中的电子迁移率非常高，随着厚度的减少而增加。我们报道的锗板的迁移趋势与最近报道的实验结果一致。对于硅板，我们发现3nm是未来超薄硅器件最合适的厚度，因为它具有最低的导带变形电位和最高的电子迁移率。

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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2018 IEEE International Conference on Electronics, Computing and Communication Technologies (CONECCT)

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