T. Matsumoto, S. Maeda, H. Dang, T. Uchida, K. Ota, Y. Hirano, H. Sayama, T. Iwamatsu, T. Ipposhi, H. Oda, S. Maegawa, Y. Inoue, T. Nishimura
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Novel SOI wafer engineering using low stress and high mobility CMOSFET with <100>-channel for embedded RF/analog applications
For high performance RF/analog and logic device technology, novel SOI wafer engineering featuring <100>-channel SOI CMOSFET with high-resistivity substrate is proposed. Mobility of PMOSFET is improved about 16% by changing a channel direction from <110> to <100>. Moreover, the reduction of the drive current in narrow channel PMOSFET is suppressed. The maximum oscillation frequency (f/sub max/) for NMOSFET is improved around 7% by changing the buried oxide (BOX) thickness from 400 nm to 150 nm because the self-heating effect is suppressed, and is improved around 5% by changing the substrate resistivity from 10 /spl Omega/cm to 1000 /spl Omega/cm because the power loss is reduced. In this work, the wafer engineering which consists of 1) <100>-channel, 2) optimization of BOX, and 3) high resistivity substrate, is proposed to improve the RF performance of the CMOSFET.
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