Title :
50-nm gate Schottky source/drain p-MOSFETs with a SiGe channel
Author :
Ikeda, K. ; Yamashita, Y. ; Endoh, A. ; Fukano, T. ; Hikosaka, K. ; Mimura, T.
Author_Institution :
Fujitsu Labs. Ltd., Kanagawa, Japan
Abstract :
We propose new SiGe channel p-MOSFETs with germano-silicide Schottky source/drains (S/Ds). The Schottky barrier-height (SBH) for SiGe is expected to be low enough to improve the injection of carriers into the SiGe channel and, as a result, current drivability is also expected to improve. We demonstrate the proposed Schottky S/D p-MOSFETs down to a 50-nm gate-length. The drain current and transconductance are -339 μA/μm and 285 μS/μm at V/sub GS/=V/sub DS/=-1.5 V, respectively. By increasing the Ge content in the SiGe channel from 30% to 35%, the drive current. and transconductance can be improved up to 23% and 18%, respectively. This is partly due to the lower barrier-height for strained Si/sub 0.65/Ge/sub 0.35/ channel than those for strained Si/sub 0.7/Ge/sub 0.3/ channel device and partly due to the lower effective mass of the holes.
Keywords :
Ge-Si alloys; MOSFET; Schottky barriers; effective mass; leakage currents; semiconductor materials; -1.5 V; 0.285 muS/mm; 285 muS; 50 nm; Ge content; Schottky barrier-height; Schottky source/drain p-MOSFETs; Si/sub 0.65/Ge/sub 0.35/; SiGe channel p-MOSFETs; carrier injection; current drivability improvement; drain current; effective mass; p-channel MOSFET; strained Si/sub 0.65/Ge/sub 0.35/ channel; transconductance; Doping profiles; Effective mass; Germanium silicon alloys; MOSFET circuits; Photonic band gap; Schottky barriers; Silicides; Silicon germanium; Transconductance; Two dimensional displays;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2002.805007
