The annihilation of threading dislocations in the germanium epitaxially grown within the silicon nanoscale trenches

Guang Li Luo; Shih Chiang Huang; Chih Hsin Ko; Clement H. Wann; Cheng Ting Chung; Zong You Han; Chao Ching Cheng; Chun Yen Chang; Hau Yu Lin; Chao-Hsin Chien

doi:10.1149/1.3158832

The annihilation of threading dislocations in the germanium epitaxially grown within the silicon nanoscale trenches

Guang Li Luo^*, Shih Chiang Huang, Chih Hsin Ko, Clement H. Wann, Cheng Ting Chung, Zong You Han, Chao Ching Cheng, Chun Yen Chang, Hau Yu Lin, Chao-Hsin Chien

^*Corresponding author for this work

International College of Semiconductor Technology

Research output: Contribution to journal › Article › peer-review

7 Scopus citations

Abstract

We investigated the selective growth of germanium into nanoscale trenches on silicon substrates. These nanoscale trenches, the smallest size of which was 50 nm, were fabricated using the state-of-the-art shallow trench isolation technique. The quality of the Ge films was evaluated using transmission electron microscopy. The formation of threading dislocations (TDs) was effectively suppressed when using this deposition technique. For the Ge grown in nanoscale Si areas (e.g., several tens of nanometers), the TDs were probably readily removed during cyclic thermal annealing predominantly because their gliding distance to the SiO₂ sidewalls was very short. Therefore, nanoscale epitaxial growth technology can be used to deposit Ge films on lattice-mismatched Si substrates with a reduced defect density.

Original language	English
Journal	Journal of the Electrochemical Society
Volume	156
Issue number	9
DOIs	https://doi.org/10.1149/1.3158832
State	Published - 7 Aug 2009

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title = "The annihilation of threading dislocations in the germanium epitaxially grown within the silicon nanoscale trenches",

abstract = "We investigated the selective growth of germanium into nanoscale trenches on silicon substrates. These nanoscale trenches, the smallest size of which was 50 nm, were fabricated using the state-of-the-art shallow trench isolation technique. The quality of the Ge films was evaluated using transmission electron microscopy. The formation of threading dislocations (TDs) was effectively suppressed when using this deposition technique. For the Ge grown in nanoscale Si areas (e.g., several tens of nanometers), the TDs were probably readily removed during cyclic thermal annealing predominantly because their gliding distance to the SiO2 sidewalls was very short. Therefore, nanoscale epitaxial growth technology can be used to deposit Ge films on lattice-mismatched Si substrates with a reduced defect density.",

author = "Luo, {Guang Li} and Huang, {Shih Chiang} and Ko, {Chih Hsin} and Wann, {Clement H.} and Chung, {Cheng Ting} and Han, {Zong You} and Cheng, {Chao Ching} and Chang, {Chun Yen} and Lin, {Hau Yu} and Chao-Hsin Chien",

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T1 - The annihilation of threading dislocations in the germanium epitaxially grown within the silicon nanoscale trenches

AU - Luo, Guang Li

AU - Huang, Shih Chiang

AU - Ko, Chih Hsin

AU - Wann, Clement H.

AU - Chung, Cheng Ting

AU - Han, Zong You

AU - Cheng, Chao Ching

AU - Chang, Chun Yen

AU - Lin, Hau Yu

AU - Chien, Chao-Hsin

PY - 2009/8/7

Y1 - 2009/8/7

N2 - We investigated the selective growth of germanium into nanoscale trenches on silicon substrates. These nanoscale trenches, the smallest size of which was 50 nm, were fabricated using the state-of-the-art shallow trench isolation technique. The quality of the Ge films was evaluated using transmission electron microscopy. The formation of threading dislocations (TDs) was effectively suppressed when using this deposition technique. For the Ge grown in nanoscale Si areas (e.g., several tens of nanometers), the TDs were probably readily removed during cyclic thermal annealing predominantly because their gliding distance to the SiO2 sidewalls was very short. Therefore, nanoscale epitaxial growth technology can be used to deposit Ge films on lattice-mismatched Si substrates with a reduced defect density.

AB - We investigated the selective growth of germanium into nanoscale trenches on silicon substrates. These nanoscale trenches, the smallest size of which was 50 nm, were fabricated using the state-of-the-art shallow trench isolation technique. The quality of the Ge films was evaluated using transmission electron microscopy. The formation of threading dislocations (TDs) was effectively suppressed when using this deposition technique. For the Ge grown in nanoscale Si areas (e.g., several tens of nanometers), the TDs were probably readily removed during cyclic thermal annealing predominantly because their gliding distance to the SiO2 sidewalls was very short. Therefore, nanoscale epitaxial growth technology can be used to deposit Ge films on lattice-mismatched Si substrates with a reduced defect density.

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The annihilation of threading dislocations in the germanium epitaxially grown within the silicon nanoscale trenches

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