Inverse Scaling Trends for Charge-Trapping-Induced Degradation of FinFETs Performance

Author

Amoroso, S.M. ; Georgiev, V.P. ; Gerrer, L. ; Towie, E. ; Xingsheng Wang ; Riddet, C. ; Brown, A.R. ; Asenov, A.

Author_Institution

Device Modeling Group, Univ. of Glasgow, Glasgow, UK

Volume

61

Issue

12

fYear

2014

fDate

Dec. 2014

Firstpage

4014

Lastpage

4018

Abstract

In this paper, we investigate the impact of a single discrete charge trapped at the top oxide interface on the performance of scaled nMOS FinFET transistors. The charge-trapping-induced gate voltage shift is simulated as a function of the device scaling and for several regimes of conduction-from subthreshold to ON-state. Contrary to what is expected for planar MOSFETs, we show that the trap impact decreases with scaling down the FinFET size and the applied gate voltage. By comparing drift-diffusion with nonequilibrium Green functions simulations, we show that quantum effects in the charge distribution and transport can reduce or amplify the impact of discrete traps in simulation of reliability resilience of scaled FinFETs.

Keywords

MOSFET; electron traps; hole traps; semiconductor device models; FinFET performance; charge trapping induced degradation; charge trapping induced gate voltage shift; inverse scaling trends; nMOS FinFET; nonequilibrium Green functions; planar MOSFET; top oxide interface; FinFETs; Logic gates; Market research; Oxidation; Performance evaluation; CMOS scaling; Charge-trapping; FinFET; nonequilibrium Green function (NEGF); quantum transport; reliability; reliability.;

fLanguage

English

Journal_Title

Electron Devices, IEEE Transactions on

Publisher

ieee

ISSN

0018-9383

Type

jour

DOI

10.1109/TED.2014.2363212

Filename

6937192