Title :
SiGe source/drain structure for the suppression of the short-channel effect of sub-0.1-μm p-channel MOSFETs
Author :
Nishiyama, Akira ; Matsuzawa, Kazuya ; Takagi, Shin-ichi
Author_Institution :
R&D Center, Toshiba Corp., Yokohama, Japan
fDate :
6/1/2001 12:00:00 AM
Abstract :
A bandgap engineering technique is proposed for the suppression of the short-channel effect (SCE) and its effectiveness is quantitatively calculated in the case of the SiGe source/drain structure with a device simulation. The drain-induced barrier lowering (DIBL) and the charge sharing are suppressed by the presence of the valence band discontinuity between the SiGe source/drain and Si channel. In order to obtain the full advantage of this structure, it is necessary to locate the SiGe layers both at the source/drain regions and the SiSe/Si interface at the pn junction or inside the channel region. The effectiveness increases with the increase of the valence band discontinuity (Ge concentration). As a result of the suppression of the SCE and the reduction of the minimum gate length, the drain current increases, and thus high-speed operation can be realized with this technique
Keywords :
Ge-Si alloys; MOSFET; elemental semiconductors; energy gap; semiconductor device models; semiconductor materials; silicon; 0.1 micron; SiGe-Si; bandgap engineering technique; charge sharing; device simulation; drain current increases; drain-induced barrier lowering; high-speed operation; minimum gate length; p-channel MOSFETs; short-channel effect; source/drain structure; valence band discontinuity; Degradation; Doping; Germanium silicon alloys; Helium; Large scale integration; MOSFETs; Photonic band gap; Region 1; Silicon germanium; Ultra large scale integration;
Journal_Title :
Electron Devices, IEEE Transactions on
