Management of Phonon Transport in Lateral Direction for Gap-Controlled Si Nanopillar/SiGe Interlayer Composite Materials

IF 1.8 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY IEEE Open Journal of Nanotechnology Pub Date : 2021-11-30 DOI:10.1109/OJNANO.2021.3131165

Daisuke Ohori;Min-Hui Chuang;Asahi Sato;Sou Takeuchi;Masayuki Murata;Atsushi Yamamoto;Ming-Yi Lee;Kazuhiko Endo;Yiming Li;Jenn-Hwan Tarng;Yao-Jen Lee;Seiji Samukawa

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引用次数: 1

Abstract

The phonon transport in the lateral direction for gap-controlled Si nanopillar (NP) /SiGe interlayer composite materials was investigated to eliminate heat generation in the channel area for advanced MOS transistors. The gap-controlled Si NP/SiGe composite layer showed 1/250 times lower thermal conductivity than Si bulk. Then, the phonon transport behavior in lateral direction could be predicted by the combination between the 3-omega measurement method for thermal conductivity and the Landauer approach for phonon transport in Si NP/Si _0.7 Ge _0.3 interlayer composite structure. We found that the NP structure could regulate the phonon transport in the lateral direction by changing the NP gaps by preventing the phonon transportation from the drain region and the potential heat generation. As such, this structure achieves the first step toward phonon transport management in the same electron transportation direction of planar-type MOSFETs and represents a promising solution to heat generation for advanced CMOS devices.

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间隙控制的硅纳米柱/SiGe夹层复合材料声子横向输运的管理

为了消除先进MOS晶体管沟道区产生的热量，研究了间隙控制的Si纳米柱/SiGe层间复合材料的横向声子输运。间隙控制的Si NP/SiGe复合层的导热系数比Si本体低1/250。然后，将3-omega测量导热系数的方法与声子输运的Landauer方法相结合，可以预测Si NP/Si0.7Ge0.3层间复合结构中声子的横向输运行为。我们发现NP结构可以通过改变NP间隙来调节声子的横向输运，从而阻止声子从漏区输运和潜在的热量产生。因此，该结构在平面型mosfet的相同电子输运方向上实现了声子输运管理的第一步，并代表了先进CMOS器件发热的有前途的解决方案。

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