Electron transfer between adjacent channels simulated by ensemble Monte Carlo methods
- 15 March 1987
- journal article
- Published by AIP Publishing in Journal of Applied Physics
- Vol. 61 (6) , 2395-2398
- https://doi.org/10.1063/1.337956
Abstract
The transfer of electrons between two channels, which are viewed as constituents of a ‘‘generic device’’ is studied. A many-particle Monte Carlo model with self-consistent electric fields is used for this analysis. The study has been performed to assess switching speeds associated with various novel devices, such as velocity modulation transistors and dual-channel high-electron mobility transistors. Typical switching time constants for a 1-μm device (0.4-μm gate length) are 3.5 ps for the longitudinal (source-to-drain) switch on, and 0.2 ps for the transport perpendicular to the interfaces between the two channels.This publication has 5 references indexed in Scilit:
- Scaling properties of high electron mobility transistorsIEEE Transactions on Electron Devices, 1986
- Physics and modelling of hot electron effects in submicron devicesPhysica B+C, 1985
- Calculation of the electron velocity distribution in high electron mobility transistors using an ensemble Monte Carlo methodJournal of Applied Physics, 1985
- A Proposal of Single Quantum Well Transistor (SQWT) –Self-Consistent Calculations of 2D Electrons in a Quantum Well with External VoltageJapanese Journal of Applied Physics, 1984
- Velocity-Modulation Transistor (VMT) –A New Field-Effect Transistor ConceptJapanese Journal of Applied Physics, 1982