DocumentCode
1759220
Title
Electronic Structure and Infrared Light Emission in Dislocation-Engineered Silicon
Author
Cheng-Lun Hsin ; Hsu-Shen Teng ; Hsiang-Yuan Lin ; Tzu-Hsuan Cheng ; Chao-Chia Cheng ; Po-Liang Liu
Author_Institution
Dept. of Electr. Eng., Nat. Central Univ., Chungli, Taiwan
Volume
14
Issue
3
fYear
2015
fDate
42125
Firstpage
399
Lastpage
403
Abstract
One of the perspectives of the Si-based technology is the optical interconnect for data transmission and applications in optoelectronic integrated circuit. In this report, the engineered dislocation network was proposed, and the atomic structure of the dislocation array was revealed by high-resolution transmission electron microscope and scanning tunneling microscope. The photoluminescence emission is strong and compatible with intrinsic Si characteristic peak, making it possible as light emitters in silicon. The analysis of dislocation array-induced scanning tunneling spectroscopy identified the presence of defect levels under the conduction band, compared with the occupied and unoccupied Kohn-Sham orbitals in the forbidden gap of Si derived from first-principles theoretical models. This study demonstrated the possibility of dislocation-induced optical transition from a theoretical and experimental perspective, which will be essential in the development of Si-based optoelectronic integrated circuit.
Keywords
ab initio calculations; conduction bands; defect states; dislocation arrays; elemental semiconductors; energy gap; photoluminescence; scanning tunnelling microscopy; silicon; transmission electron microscopy; Si; Si-based optoelectronic integrated circuit; Si-based technology; atomic structure; conduction band; data transmission; defect levels; dislocation array; dislocation network engineering; dislocation-engineered silicon; dislocation-induced optical transition; electronic structure; first-principles theoretical models; forbidden gap; high-resolution transmission electron microscopy; infrared light emission; light emitters; optical interconnect; optoelectronic integrated circuit; photoluminescence emission; scanning tunneling microscopy; scanning tunneling spectroscopy; Arrays; Educational institutions; Integrated circuits; Photonic band gap; Silicon; Slabs; Tunneling; Density of state; dislocation array; first-principles calculations; network; photoluminescence; tunneling current;
fLanguage
English
Journal_Title
Nanotechnology, IEEE Transactions on
Publisher
ieee
ISSN
1536-125X
Type
jour
DOI
10.1109/TNANO.2015.2411292
Filename
7056478
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