Title :
Accurate Calculation of Gate Tunneling Current in Double-Gate and Single-Gate SOI MOSFETs Through Gate Dielectric Stacks
Author :
Chaves, Ferney A. ; Jiménez, David ; Ruiz, Francisco J García ; Godoy, Andrés ; Suñé, Jordi
Author_Institution :
Dept. d´´Eng. Electron., Univ. Autonoma de Barcelona, Barcelona, Spain
Abstract :
Recently, a new generation of MOSFETs, called multigate transistors, has emerged with geometries that will allow the downscaling and continuing enhancement of computer performance into next decade. The low dimensions in these nanoscale transistors exhibit increasing quantum effects, which are no longer negligible. Gate tunneling current is one of such effects that should be efficiently modeled. In this paper, an accurate description of tunneling in ultrathin body double-gate and single-gate MOSFET devices through layers of high- κ dielectrics, which relies on the precise determination of quasi-bound states, is developed. For this purpose, the perfectly matched layer method is embedded in each iteration of a 1-D Schrödinger-Poisson solver by introducing a complex stretched coordinate which allows applying artificial absorbing layers in the boundaries.
Keywords :
MOSFET; Schrodinger equation; elemental semiconductors; geometry; iterative methods; silicon; silicon-on-insulator; stochastic processes; tunnelling; 1D Schrödinger-Poisson solver; Si; artificial absorbing layer; complex stretch coordination; computer performance enhancement; gate tunneling current calculation; geometry; high-k gate dielectric stack; iteration method; multigate transistor; nanoscale transistor; perfectly matched layer method; quantum effect; quasibound state determination; ultrathin body double-gate SOI MOSFET device; ultrathin body single-gate SOI MOSFET device; Dielectrics; Logic gates; MOSFETs; Metals; Silicon; Tunneling; Wave functions; Absorbing boundary conditions; double-gate MOSFETs; high- $kappa$ (HK) dielectrics; leakage tunneling current; modeling; perfectly matched method;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2012.2206597
