Manipulation of strain state in silicon nanoribbons by top-down approach

Zhiqiang Mu; Miao Zhang; Zhongying Xue; Gaodi Sun; Qinglei Guo; Da Chen; Gaoshan Huang; Yongfeng Mei; Paul K. Chu; Zengfeng Di; Xi Wang

doi:10.1063/1.4919630

Manipulation of strain state in silicon nanoribbons by top-down approach

Zhiqiang Mu, Miao Zhang, Zhongying Xue, Gaodi Sun, Qinglei Guo, Da Chen, Gaoshan Huang, Yongfeng Mei, Paul K. Chu, Zengfeng Di^*, Xi Wang

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

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Abstract

Tensile strain is often utilized to enhance the electron mobility and luminescent characteristics of semiconductors. A top-down approach in conjunction with roll-up technology is adopted to produce high tensile strain in Si nanoribbons by patterning and releasing of the bridge-like structures. The tensile strain can be altered between uniaxial state and biaxial state by adjusting the dimensions of the patterns and can be varied controllably up to 3.2% and 0.9% for the uniaxial- and biaxial-strained Si nanoribbons, respectively. Three-dimensional finite element analysis is performed to investigate the mechanism of strain generation during patterning and releasing of the structure. Since the process mainly depends on the geometrical factors, the technique can be readily extended to other types of mechanical, electrical, and optical membranes.

Original language	English
Article number	174102
Journal	Applied Physics Letters
Volume	106
Issue number	17
DOIs	https://doi.org/10.1063/1.4919630
Publication status	Published - 27 Apr 2015

Publisher's Copyright Statement

COPYRIGHT TERMS OF DEPOSITED FINAL PUBLISHED VERSION FILE: This article may be downloaded for personal use only. Any other use requires prior permission of the author and AIP Publishing. This article appeared in Zhiqiang Mu, Miao Zhang, Zhongying Xue, Gaodi Sun, Qinglei Guo, Da Chen, Gaoshan Huang, Yongfeng Mei, Paul K. Chu, Zengfeng Di, and Xi Wang , "Manipulation of strain state in silicon nanoribbons by top-down approach", Appl. Phys. Lett. 106, 174102 (2015) and may be found at https://doi.org/10.1063/1.4919630.

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title = "Manipulation of strain state in silicon nanoribbons by top-down approach",

abstract = "Tensile strain is often utilized to enhance the electron mobility and luminescent characteristics of semiconductors. A top-down approach in conjunction with roll-up technology is adopted to produce high tensile strain in Si nanoribbons by patterning and releasing of the bridge-like structures. The tensile strain can be altered between uniaxial state and biaxial state by adjusting the dimensions of the patterns and can be varied controllably up to 3.2% and 0.9% for the uniaxial- and biaxial-strained Si nanoribbons, respectively. Three-dimensional finite element analysis is performed to investigate the mechanism of strain generation during patterning and releasing of the structure. Since the process mainly depends on the geometrical factors, the technique can be readily extended to other types of mechanical, electrical, and optical membranes.",

author = "Zhiqiang Mu and Miao Zhang and Zhongying Xue and Gaodi Sun and Qinglei Guo and Da Chen and Gaoshan Huang and Yongfeng Mei and Chu, {Paul K.} and Zengfeng Di and Xi Wang",

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language = "English",

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T1 - Manipulation of strain state in silicon nanoribbons by top-down approach

AU - Mu, Zhiqiang

AU - Zhang, Miao

AU - Xue, Zhongying

AU - Sun, Gaodi

AU - Guo, Qinglei

AU - Chen, Da

AU - Huang, Gaoshan

AU - Mei, Yongfeng

AU - Chu, Paul K.

AU - Di, Zengfeng

AU - Wang, Xi

PY - 2015/4/27

Y1 - 2015/4/27

N2 - Tensile strain is often utilized to enhance the electron mobility and luminescent characteristics of semiconductors. A top-down approach in conjunction with roll-up technology is adopted to produce high tensile strain in Si nanoribbons by patterning and releasing of the bridge-like structures. The tensile strain can be altered between uniaxial state and biaxial state by adjusting the dimensions of the patterns and can be varied controllably up to 3.2% and 0.9% for the uniaxial- and biaxial-strained Si nanoribbons, respectively. Three-dimensional finite element analysis is performed to investigate the mechanism of strain generation during patterning and releasing of the structure. Since the process mainly depends on the geometrical factors, the technique can be readily extended to other types of mechanical, electrical, and optical membranes.

AB - Tensile strain is often utilized to enhance the electron mobility and luminescent characteristics of semiconductors. A top-down approach in conjunction with roll-up technology is adopted to produce high tensile strain in Si nanoribbons by patterning and releasing of the bridge-like structures. The tensile strain can be altered between uniaxial state and biaxial state by adjusting the dimensions of the patterns and can be varied controllably up to 3.2% and 0.9% for the uniaxial- and biaxial-strained Si nanoribbons, respectively. Three-dimensional finite element analysis is performed to investigate the mechanism of strain generation during patterning and releasing of the structure. Since the process mainly depends on the geometrical factors, the technique can be readily extended to other types of mechanical, electrical, and optical membranes.

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U2 - 10.1063/1.4919630

DO - 10.1063/1.4919630

M3 - RGC 21 - Publication in refereed journal

SN - 0003-6951

VL - 106

JO - Applied Physics Letters

JF - Applied Physics Letters

IS - 17

M1 - 174102

ER -

Manipulation of strain state in silicon nanoribbons by top-down approach

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