Low-temperature electron transport in [110] and [100] silicon nanowires: a DFT-Monte Carlo study
Journal article, 2024

The effects of very low temperature on the electron transport in a [110] and [100] axially aligned unstrained silicon nanowires (SiNWs) are investigated. A combination of semi-empirical 10-orbital tight-binding method, density functional theory and Ensemble Monte Carlo (EMC) methods are used. Both acoustic and optical phonons are included in the electron-phonon scattering rate calculations covering both intra-subband and inter-subband events. A comparison with room temperature (300 K) characteristics shows that for both nanowires, the average electron steady-state drift velocity increases at least 2 times at relatively moderate electric fields and lower temperatures. Furthermore, the average drift velocity in [110] nanowires is 50 percent more than that of [100] nanowires, explained by the difference in their conduction subband effective mass. Transient average electron velocity suggests that there is a pronounced streaming electron motion at low temperature which is attributed to the reduced electron-phonon scattering rates.

electron-phonon scattering

DFT

cryogenic

CMOS

silicon nanowire

ensemble Monte Carlo

spin qubit

Author

Daryoush Shiri

Chalmers, Microtechnology and Nanoscience (MC2), Quantum Technology

Reza Nekovei

Frank H. Dotterweich College of Engineering

Amit Verma

Frank H. Dotterweich College of Engineering

Frontiers in Nanotechnology

26733013 (eISSN)

Vol. 6 1494814

Subject Categories

Condensed Matter Physics

DOI

10.3389/fnano.2024.1494814

More information

Latest update

12/18/2024