Title :
Atomistic-Level Modeling for Thickness Dependence of Electron Mobility in InSb QW-FETs
Author :
Guan, Ximeng ; Lu, Jing ; Wang, Yan ; Yu, Zhiping
Author_Institution :
Inst. of Microelectron., Tsinghua Univ., Beijing
Abstract :
The thickness dependence of electron mobility in the InSb quantum well (QW) FETs are calculated based on an atomistic approach for bandstructure calculation. The electron effective mass (m*) is computed using fast yet accurate sp3d5s* tight-binding (TB) method for InSb quantum-well (QW) (or ultra-thin-body, UTB) with thickness of 3-16 nm. The m* dependence on the UTB thickness is then used in determining the electron mobility in the channel region of InSb QW-FETs. It is found that in QW-FETs, optical phonon scattering is a dominant factor, which is in turn strongly coupled to the carrier effective mass determined by channel thickness. The thickness dependence of electron mobility differs from that of the MOSFETs, where surface roughness is one of the major scattering mechanisms
Keywords :
III-V semiconductors; effective mass; electron mobility; field effect transistors; indium compounds; quantum well devices; semiconductor device models; semiconductor quantum wells; surface roughness; tight-binding calculations; InSb; MOSFETs; QW FETs; bandstructure calculation; electron effective mass; electron mobility; optical phonon scattering; quantum well FETs; surface roughness; tight-binding method; Atomic measurements; Effective mass; Electron mobility; Electron optics; FETs; Optical scattering; Particle scattering; Phonons; Quantum computing; Quantum wells; Indium Antimonide (InSb); bandstructure; effective mass; mobility; ultra-thin-body (UTB);
Conference_Titel :
Simulation of Semiconductor Processes and Devices, 2006 International Conference on
Conference_Location :
Monterey, CA
Print_ISBN :
1-4244-0404-5
DOI :
10.1109/SISPAD.2006.282882
