Disposable polysilicon LDD spacer technology

Author

Parrillo, Louis C. ; Pfiester, James R. ; Lin, Jung-Hui ; Travis, Edward O. ; Sivan, Richard D. ; Gunderson, Craig D.

Author_Institution

Motorola Inc., Austin, TX, USA

Volume

38

Issue

1

fYear

1991

fDate

1/1/1991 12:00:00 AM

Firstpage

39

Lastpage

46

Abstract

An advanced 0.5-μm CMOS disposable lightly doped drain (LDD) spacer technology has been developed. This 0.5-μm CMOS technology features surface-channel LDD NMOS and PMOS devices, n⁺/p⁺ poly gates, 125-A-thick gate oxide, and Ti-salicided source/drain/gate regions. Using only two masking steps, the NMOS and PMOS LDD spacers are defined separately to provide deep arsenic n⁺ regions for lower salicided junction leakage, while simultaneously providing shallow phosphorus n^- and boron p^- regions for improved device short-channel effects. Additionally, the process allows independent adjustment of the LDD and salicide spacers to optimize the LDD design while avoiding salicide bridging of source/drain to gate regions. The results indicate extrapolated DC hot-carrier lifetimes in excess of 10 years for a 0.3-μm electrical channel-length NMOS device operated at a power-supply voltage of 3.3 V

Keywords

CMOS integrated circuits; carrier lifetime; hot carriers; integrated circuit technology; leakage currents; 0.5 micron; CMOS disposable LDD spacer technology; DC hot-carrier lifetimes; Si-SiO₂; Si-TiSi₂; Si:As; Si:B; Si:P; Ti-salicided source/drain/gate regions; deep n⁺ regions; masking steps; n⁺/p⁺ poly gates; polysilicon LDD spacer technology; salicided junction leakage; short-channel effects; surface channel LDD PMOS devices; surface-channel LDD NMOS; Annealing; Boron; CMOS process; CMOS technology; Design optimization; Implants; MOS devices; Resists; Space technology; Voltage;

fLanguage

English

Journal_Title

Electron Devices, IEEE Transactions on

Publisher

ieee

ISSN

0018-9383

Type

jour

DOI

10.1109/16.65734

Filename

65734