Schottky Source/Drain CMOS Device Optimization with Dopant-Segregated NiPt Silicide

Author

Huang, Y.T. ; Liu, P.W. ; Chiang, W.T. ; Tsai, T.L. ; Tsai, C.H. ; Tsai, C.T. ; Ma, G.H.

Author_Institution

United Microelectron. Corp. (UMC), Tainan

fYear

2008

Firstpage

38

Lastpage

39

Abstract

We have successfully demonstrated an optimized dopant- segregated Schottky (DSS) source/drain CMOS technology featuring 35 nm physical gate length and 1.2 nm gate oxide. Several important device characteristics, including sidewall gate junction leakage suppression, short channel effect (SCE) control, along with drive current performance, are all investigated in this work. Furthermore, we notice that halo implant process is indispensable for providing the wider process window, which is realized by compensating the sensitive dopant segregation implantation (DSI) process. Without any supplement of additional process-induced stress, the DSS N/PMOS drive current of 100 nA/um and 510 uA/um at I_off=100 nA/um and V_dd=1.2 V are obtained. Moreover, an 11% I_on improvement can be achieved in the optimized DSS NMOS.

Keywords

MOSFET; ion implantation; nickel compounds; semiconductor doping; NMOS; PMOS; dopant segregation implantation; dopant-segregated Schottky source-drain CMOS technology; short channel effect; sidewall gate junction leakage suppression; size 35 nm; voltage 1.2 V; CMOS process; CMOS technology; Decision support systems; Fabrication; Implants; MOS devices; Microelectronics; Schottky barriers; Silicides; Stress;

fLanguage

English

Publisher

ieee

Conference_Titel

VLSI Technology, Systems and Applications, 2008. VLSI-TSA 2008. International Symposium on

Conference_Location

Hsinchu

ISSN

1524-766X

Print_ISBN

978-1-4244-1614-1

Electronic_ISBN

1524-766X

Type

conf

DOI

10.1109/VTSA.2008.4530788

Filename

4530788