A three-terminal band-trap-band tunneling model for drain engineering and substrate bias effect on GIDL in MOSFET

Jyh-Chyurn Guo; Yuan Chang Liu; M. H. Chou; M. T. Wang; F. Shone

doi:10.1109/16.701483

A three-terminal band-trap-band tunneling model for drain engineering and substrate bias effect on GIDL in MOSFET

Jyh-Chyurn Guo^*, Yuan Chang Liu, M. H. Chou, M. T. Wang, F. Shone

^*Corresponding author for this work

Institute of Electronics

Research output: Contribution to journal › Article › peer-review

22 Scopus citations

Abstract

A new three-terminal partial band-trap-band tunneling (BTB) model is proposed to predict the drain engineering effect and substrate bias effect on gate-induced-drain-leakage (GIDL) characteristics for virgin devices free from electric stress. The lateral field EL and the ratio of lateral field w.r.t. total field e (EL IE) are two key factors responsible for the tunneling barrier lowering and the enhancement of GIDL. The principle to suppress GIDL are two-fold: the first one is to eliminate process induced intrinsic interface states and the second one is to minimize EL and EL l E by using drain engineering or changing bias conditions such as applying forward substrate biases.

Original language	English
Pages (from-to)	1518-1523
Number of pages	6
Journal	IEEE Transactions on Electron Devices
Volume	45
Issue number	7
DOIs	https://doi.org/10.1109/16.701483
State	Published - 1 Dec 1998

Keywords

Band-to-band tunneling
Drain engineering
GIDL

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10.1109/16.701483

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title = "A three-terminal band-trap-band tunneling model for drain engineering and substrate bias effect on GIDL in MOSFET",

abstract = "A new three-terminal partial band-trap-band tunneling (BTB) model is proposed to predict the drain engineering effect and substrate bias effect on gate-induced-drain-leakage (GIDL) characteristics for virgin devices free from electric stress. The lateral field EL and the ratio of lateral field w.r.t. total field e (EL IE) are two key factors responsible for the tunneling barrier lowering and the enhancement of GIDL. The principle to suppress GIDL are two-fold: the first one is to eliminate process induced intrinsic interface states and the second one is to minimize EL and EL l E by using drain engineering or changing bias conditions such as applying forward substrate biases.",

keywords = "Band-to-band tunneling, Drain engineering, GIDL",

author = "Jyh-Chyurn Guo and Liu, {Yuan Chang} and Chou, {M. H.} and Wang, {M. T.} and F. Shone",

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T1 - A three-terminal band-trap-band tunneling model for drain engineering and substrate bias effect on GIDL in MOSFET

AU - Guo, Jyh-Chyurn

AU - Liu, Yuan Chang

AU - Chou, M. H.

AU - Wang, M. T.

AU - Shone, F.

PY - 1998/12/1

Y1 - 1998/12/1

N2 - A new three-terminal partial band-trap-band tunneling (BTB) model is proposed to predict the drain engineering effect and substrate bias effect on gate-induced-drain-leakage (GIDL) characteristics for virgin devices free from electric stress. The lateral field EL and the ratio of lateral field w.r.t. total field e (EL IE) are two key factors responsible for the tunneling barrier lowering and the enhancement of GIDL. The principle to suppress GIDL are two-fold: the first one is to eliminate process induced intrinsic interface states and the second one is to minimize EL and EL l E by using drain engineering or changing bias conditions such as applying forward substrate biases.

AB - A new three-terminal partial band-trap-band tunneling (BTB) model is proposed to predict the drain engineering effect and substrate bias effect on gate-induced-drain-leakage (GIDL) characteristics for virgin devices free from electric stress. The lateral field EL and the ratio of lateral field w.r.t. total field e (EL IE) are two key factors responsible for the tunneling barrier lowering and the enhancement of GIDL. The principle to suppress GIDL are two-fold: the first one is to eliminate process induced intrinsic interface states and the second one is to minimize EL and EL l E by using drain engineering or changing bias conditions such as applying forward substrate biases.

KW - Band-to-band tunneling

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A three-terminal band-trap-band tunneling model for drain engineering and substrate bias effect on GIDL in MOSFET

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