Physically-based modeling for hole scattering rate in strained Si_1-xGe_x/(100)Si

WANG Bin(王斌)^{1, 2}, HU Hui-yong(胡辉勇)², ZHANG He-ming(张鹤鸣)², SONG Jian-jun(宋建军)², ZHANG Yu-ming(张玉明)²

(1. School of Advanced Materials and Nanotechnology, Xidian University, Xi’an 710071, China;
2. Key Lab of Wide Band-Gap Semiconductor Materials and Devices
(School of Microelectronics, Xidian University), Xi’an 710071, China)

Abstract:based on the Fermi’s golden rule and the theory of Boltzmann collision term approximation, a physically-based model for hole scattering rate (SR) in strained Si_1-xGe_x/(100)Si was presented, which takes into account a variety of scattering mechanisms, including ionized impurity, acoustic phonon, non-polar optical phonon and alloy disorder scattering. It is indicated that the SRs of acoustic phonon and non-polar optical phonon decrease under the strain, and the total SR in strained Si_1-xGe_x/(100)Si also decreases obviously with increasing Ge fraction (x). Moreover, the total SR continues to show a constant tendency when x is less than 0.3. In comparison with bulk Si, the total SR of strained Si_1-xGe_x/(100) Si decreases by about 58%.

Key words:strained Si_1-xGe_x; biaxial stress; hole scattering rate; effective mass