Title :
Key differences for process-induced uniaxial vs. substrate-induced biaxial stressed Si and Ge channel MOSFETs
Author :
Thompson, S.E. ; Sun, G. ; Wu, K. ; Lim, J. ; Nishida, T.
Author_Institution :
Florida Univ., Gainesville, FL, USA
Abstract :
For both n and pMOSFETs, this paper confirms via controlled wafer bending experiments and physical modeling the superiority of uniaxial over biaxial stressed Si and Ge MOSFETs. For uniaxial stressed p-MOSFETs, valence band warping creates favorable in and out-of-plane conductivity effective masses resulting in significantly larger hole mobility enhancement at low strain and high vertical field. For process-induced uniaxial stressed n-MOSFETs, a significant performance advantage results from a smaller threshold voltage shift due to less bandgap narrowing and the gate also being strained.
Keywords :
MOSFET; bending; elemental semiconductors; germanium; hole mobility; internal stresses; semiconductor device models; silicon; Ge; Ge channel MOSFET; Si; Si channel MOSFET; bandgap narrowing; controlled wafer bending experiments; high vertical field; hole mobility enhancement; out-of-plane conductivity effective mass; process-induced uniaxial stress; substrate-induced biaxial stress; threshold voltage shift; uniaxial stressed n-MOSFET; uniaxial stressed p-MOSFET; valence band warping; Capacitive sensors; Compressive stress; Effective mass; MOSFET circuits; Photonic band gap; Semiconductor device modeling; Sun; Tensile stress; Threshold voltage; Uniaxial strain;
Conference_Titel :
Electron Devices Meeting, 2004. IEDM Technical Digest. IEEE International
Print_ISBN :
0-7803-8684-1
DOI :
10.1109/IEDM.2004.1419114
