Title :
High-mobility strained SiGe-on-insulator pMOSFETs with Ge-rich surface channels fabricated by local condensation technique
Author :
Tezuka, Tsutomu ; Nakaharai, Shu ; Moriyama, Yoshihiko ; Sugiyama, Naoharu ; Takagi, Shin-ichi
Author_Institution :
MIRAI-AIST, Kawasaki, Japan
fDate :
4/1/2005 12:00:00 AM
Abstract :
A new approach to form strained SiGe-on-insulator (SGOI) channel transistors, allowing fabrication of MOSFETs with very high Ge fraction in selected areas on a silicon-on-insulator substrate, is demonstrated. This method consists of epitaxial growth of an SiGe layer with a low Ge fraction and local oxidation processes. An obtained SGOI pMOSFET with a Ge fraction of 0.93 exhibits up to a tenfold enhancement in mobility. It is also found that MOSFETs having strained SGOI channels with thicknesses of less than 5 nm exhibit hole-mobility enhancement factors of over two. These results indicate that the local SGOI channels fabricated by the proposed technique are promising for implementation of high-mobility SiGe or Ge-channel MOSFETs in system-on-chip (SoC) devices.
Keywords :
Ge-Si alloys; MOSFET; condensation; electron mobility; elemental semiconductors; epitaxial growth; oxidation; silicon-on-insulator; Ge fraction; Ge-channel MOSFET; Ge-rich surface channel; MOSFET fabrication; SGOI pMOSFET; SiGe; SiGe layer epitaxial growth; high-mobility SiGe MOSFET; high-mobility strained SiGe-on-insulator; hole-mobility enhancement; local condensation technique; local oxidation process; mobility enhancement; silicon-on-insulator substrate; strained SiGe channel; strained SiGe-on-insulator channel transistors; surface-channel MOSFET; system-on-chip devices; ultrathin body SOI; Epitaxial growth; Fabrication; Germanium silicon alloys; MOSFETs; Oxidation; Silicon germanium; Silicon on insulator technology; Substrates; System-on-a-chip; Tunneling; Mobility enhancement; SiGe MOSFET; silicon-on-insulator (SOI) technology; strained SiGe channel; surface-channel MOSFET; ultrathin body SOI;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2005.844699
