Title :
Effects of uniaxial strain on the bandstructures of silicon nanowires
Author :
Sajjad, Redwan Noor ; Alam, Khairul ; Khosru, Quazi Deen Mohd
Author_Institution :
Dept. of Electr. & Electron. Eng., Bangladesh Univ. of Eng. & Technol., Dhaka
Abstract :
The effects of uniaxial strain on the band structures of Lt100Gt silicon nanowires of width 2.75 - 3.84 nm are studied using sp3d5s* orbital basis atomistic tight binding approach. The conduction band edge at Gamma point has almost no variation with strain and the second valley located at 0.36timespi/a of the wire Brilluoin moves down in energy with both compressive and tensile strains. The top valence band moves up in energy with both tensile and compressive strain, and therefore, the band gap reduces with both types of strain. We notice about 7% change in band gap for an application of 2% strain. The electron effective masses at Delta4 and Delta2 valleys show opposite dependence on strain, and the hole effective mass of top valence band has almost similar variation with both types of strain. We notice a significant change in hole effective mass with strain.
Keywords :
Brillouin zones; compressibility; conduction bands; effective mass; elemental semiconductors; energy gap; semiconductor quantum wires; silicon; tight-binding calculations; valence bands; Gamma point; Si; band gap; bandstructures; compressive strain; conduction band edge; electron effective masses; hole effective mass; silicon nanowires; size 2.75 nm to 3.84 nm; sp3d5s* orbital basis atomistic tight binding approach; tensile strain; uniaxial strain; valence band; wire Brilluoin; Bonding; Capacitive sensors; DH-HEMTs; Degradation; Effective mass; Nanowires; Photonic band gap; Silicon; Tensile strain; Uniaxial strain;
Conference_Titel :
Electrical and Computer Engineering, 2008. ICECE 2008. International Conference on
Conference_Location :
Dhaka
Print_ISBN :
978-1-4244-2014-8
Electronic_ISBN :
978-1-4244-2015-5
DOI :
10.1109/ICECE.2008.4769217
