Optimization of extrinsic source/drain resistance in ultrathin body double-gate FETs

Author

Shenoy, Rohit S. ; Saraswat, Krishna C.

Author_Institution

Dept. of Electr. Eng., Stanford Univ., CA, USA

Volume

2

Issue

4

fYear

2003

Firstpage

265

Lastpage

270

Abstract

Extrinsic resistance due to contacts and nonabrupt lateral extension doping profile can become a performance-limiter in ultrathin body double-gate FETs (DGFET). In this paper, two-dimensional device simulations are used to study and optimize the extrinsic resistance in a sub-20 nm gate length DGFET. For a given lateral doping gradient, the extension doping needs to be offset from the gate edge by an amount called the underlap. The current drive, and hence transistor performance, is maximized when the underlap is chosen in such a way as to balance the impact of nonabrupt doping on the short channel effects and series resistance. This optimization depends upon the maximum allowed off-state subthreshold leakage current and the electrostatic integrity of the device structure.

Keywords

MOSFET; contact resistance; semiconductor device models; semiconductor doping; 20 nm; contacts; current drive; electrostatic integrity; extension doping; extrinsic source/drain resistance; gate length DGFET; lateral doping gradient; nonabrupt lateral extension doping profile; transistor performance; two-dimensional device simulations; ultrathin body double-gate FETs; underlap; Contact resistance; Degradation; Doping profiles; Double-gate FETs; Electrostatics; Immune system; MOS devices; MOSFETs; Medical simulation; Silicon;

fLanguage

English

Journal_Title

Nanotechnology, IEEE Transactions on

Publisher

ieee

ISSN

1536-125X

Type

jour

DOI

10.1109/TNANO.2003.820780

Filename

1264879