A simulation study of CMOS performance improvement by laser annealed source/drain extension profiles

Author

Axelrad, Valery ; Al-Bayati, Amir ; Adibi, Babak ; Carey, Paul

Author_Institution

SEQUOIA Design Syst., Woodside, CA, USA

fYear

2000

fDate

2000

Firstpage

239

Lastpage

242

Abstract

Laser thermal processing (LTP) dramatically changes the feasibility of ultra shallow and highly doped source-drain extensions (SDE). In comparison to conventional rapid thermal processing (RTP) profiles, steeper profiles and higher peak concentrations are achieved. This is of particular importance for sub-100 nm devices, where limited steepness of RTP profiles can result in significant source-drain resistance (Rsd) and severe short-channel effects. In this work we demonstrate that LTP technologies can reduce the source/drain resistance Rsd by more than 70% for Lpoly below 100 nm in both NMOS and PMOS. This leads to increases in saturation currents by up to 10%. Significant improvements in very deep submicron MOSFET performance can thus be expected as a result of this new technology being deployed

Keywords

CMOS integrated circuits; MOSFET; ion implantation; laser beam annealing; CMOS performance; Lpoly; NMOS; PMOS; RTP profiles; laser annealed source/drain extension profiles; laser thermal processing; saturation currents; short-channel effects; simulation; source-drain resistance; sub-100 nm devices; very deep submicron MOSFET performance; CMOS process; CMOS technology; FETs; Implants; Laser transitions; MOS devices; Optical design; Rapid thermal processing; Simulated annealing; Thermal resistance;

fLanguage

English

Publisher

ieee

Conference_Titel

Ion Implantation Technology, 2000. Conference on

Conference_Location

Alpbach

Print_ISBN

0-7803-6462-7

Type

conf

DOI

10.1109/.2000.924134

Filename

924134