Title :
Electron Mobility in Silicon Nanowires
Author :
Ramayya, Edwin B. ; Vasileska, Dragica ; Goodnick, Stephen M. ; Knezevic, Irena
Author_Institution :
Dept. of Electr. & Comput. Eng., Wisconsin Univ., Madison, WI
Abstract :
The low-field electron mobility in rectangular silicon nanowire (SiNW) transistors was computed using a self-consistent Poisson-Schroumldinger-Monte Carlo solver. The behavior of the phonon-limited and surface-roughness-limited components of the mobility was investigated by decreasing the wire width from 30 to 8 nm, the width range capturing a crossover between two-dimensional and one-dimensional electron transport. The phonon-limited mobility, which characterizes transport at low and moderate transverse fields, is found to decrease with decreasing wire width due to an increase in the electron-phonon wavefunction overlap. In contrast, the mobility at very high transverse fields, which is limited by surface roughness scattering, increases with decreasing wire width due to volume inversion. The importance of acoustic phonon confinement is also discussed briefly
Keywords :
Monte Carlo methods; Poisson equation; SCF calculations; Schrodinger equation; electron mobility; elemental semiconductors; field effect transistors; nanoelectronics; nanowires; semiconductor device models; silicon; surface roughness; 1D electron transport; 2D electron transport; 30 to 8 nm; FET; Si; acoustic phonon confinement; electron-phonon wavefunction; low-field electron mobility; phonon scattering; self-consistent Poisson-Schrodinger-Monte Carlo simulation; silicon nanowire transistors; surface roughness scattering; Acoustic scattering; Electron mobility; MOSFETs; Nanowires; Optical scattering; Phonons; Rough surfaces; Silicon; Surface roughness; Wire; Electron mobility; silicon nanowires; surface roughness;
Journal_Title :
Nanotechnology, IEEE Transactions on
DOI :
10.1109/TNANO.2006.888521
