Sub-50-nm physical gate length CMOS technology and beyond using steep halo

被引:27
|
作者
Wakabayashi, H [1 ]
Ueki, M
Narihiro, M
Fukai, T
Ikezawa, N
Matsuda, T
Yoshida, K
Takeuchi, K
Ochiai, Y
Mogami, T
Kunio, T
机构
[1] NEC Corp Ltd, Silicon Syst Res Labs, Kanagawa 2291198, Japan
[2] NEC Corp Ltd, ULSI Device Dev Div, Kanagawa 2291198, Japan
来源
IEEE TRANSACTIONS ON ELECTRON DEVICES | 2002年 / 49卷 / 01期
关键词
CMOS; halo; reverse-order source/drain formation; source/drain extensions; spike annealing; sub-50-nm;
D O I
10.1109/16.974754
中图分类号
TM [电工技术]; TN [电子技术、通信技术];
学科分类号
0808 ; 0809 ;
摘要
ddSub-50-nm CMOS devices are investigated using steep halo and shallow source/drain extensions. By using a highramp-rate spike annealing (HRR-SA) process and high-dose halo, 45-nm CMOS devices are fabricated with drive currents of 650 and 300 muA/mum for an off current of less than 10 nA/mum at 1.2 V with T. (inv)(ox) = 2.5 nm. For an off current less than 300 nA/mum, 33-nm pMOSFETs have a high drive current of 400 muA/mum. Short-channel effect and reverse short-channel effect are suppressed simultaneously by using the HRR-SA process to activate a source/drain extension (SDE) after forming a deep source/drain (S/D). This process sequence is defined as a reverse-order S/D (R-S/D) formation. By using this formation, 24-nm nMOSFETs are achieved with a high drive current of 800 muA/mum for an off current of less than 300 nA/mum at 1.2 V. This high drive current might be a result of a steep halo structure reducing the spreading resistance of source/drain extensions.
引用
收藏
页码:89 / 95
页数:7
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