Title :
Strained silicon MOSFET technology
Author :
Hoyt, J.L. ; Nayfeh, H.M. ; Eguchi, S. ; Aberg, I. ; Xia, G. ; Drake, T. ; Fitzgerald, E.A. ; Antoniadis, D.A.
Author_Institution :
Microsystems Technol. Lab., MIT, Cambridge, MA, USA
Abstract :
Mobility and current drive improvements associated with biaxial tensile stress in Si n- and p-MOSFETs are briefly reviewed. Electron mobility enhancements at high channel doping (up to 6 /spl times/ 10/sup 18/ cm/sup -3/) are characterized in strained Si n-MOSFETs. For low inversion layer carrier concentrations, channel-dopant ionized impurity scattering does reduce the strain-induced mobility enhancement, but the enhancement is recovered at higher inversion charge concentrations, where screening is efficient. Mobility enhancement in strained Si p-MOSFETs is also discussed. There are process integration challenges and opportunities associated with this technology. Dopant diffusion, and its impact on profile engineering in strained Si CMOS structures, is one example. While the slower diffusion of B in Si/sub 1-x/Ge/sub x/ enables improved doping profile control, the diffusivity of the n-type dopants is dramatically enhanced in Si/sub 0.8/Ge/sub 0.2/.
Keywords :
Ge-Si alloys; MOSFET; doping profiles; electron mobility; elemental semiconductors; impurity scattering; internal stresses; inversion layers; semiconductor materials; silicon; MOSFETs; Si-SiGe; biaxial tensile stress; channel doping; channel-dopant ionized impurity scattering; electron mobility enhancements; inversion charge concentrations; inversion layer carrier concentrations; profile engineering; Capacitive sensors; Doping profiles; Electron mobility; Impurities; Laboratories; Light scattering; MOSFET circuits; Silicon; Strain measurement; Tensile stress;
Conference_Titel :
Electron Devices Meeting, 2002. IEDM '02. International
Conference_Location :
San Francisco, CA, USA
Print_ISBN :
0-7803-7462-2
DOI :
10.1109/IEDM.2002.1175770
