Title :
35 drive current improvement from recessed-SiGe drain extensions on 37 nm gate length PMOS
Author :
Chidambaram, P.R. ; Smith, B.A. ; Hall, L.H. ; Bu, H. ; Chakravarthi, S. ; Kim, Y. ; Samoilov, A.V. ; Kim, A.T. ; Jones, P.J. ; Irwin, R.B. ; Kim, M.J. ; Rotondaro, A.L.P. ; Machala, C.F. ; Grider, D.T.
Author_Institution :
Texas Instrum., Dallas, TX, USA
Abstract :
Results from the best reported PMOS transistor at a 37 nm gate length (Lg) built on a process with a recessed SiGe epitaxial layer are discussed. The process details include successful integration of SiGe at the drain extension (DE) location. A highly compressive SiGe layer, in close proximity to the channel, results in large hole mobility improvements. HRTEM based lattice parameter extractions confirm the compressive strain in the channel. In situ doped B in SiGe can be activated to a higher degree than implanted B in bulk Si resulting in further improvements from the lower DE resistance. Both changes combine to give an unprecedented 35% PMOS performance improvement. Process and device simulations that predict the observed parametric behavior quantitatively isolate the improvements to be ∼ 28% from stress and 7% from DE resistance improvement.
Keywords :
CMOS integrated circuits; Ge-Si alloys; MOSFET; transmission electron microscopy; 35% drive current improvement; 37 nm; 37 nm gate length PMOS; HRTEM; SiGe; large hole mobility; lattice parameter extractions; recessed-SiGe drain extensions; Capacitive sensors; Compressive stress; Epitaxial layers; Etching; Germanium silicon alloys; Instruments; Lattices; MOSFETs; Parameter extraction; Silicon germanium;
Conference_Titel :
VLSI Technology, 2004. Digest of Technical Papers. 2004 Symposium on
Print_ISBN :
0-7803-8289-7
DOI :
10.1109/VLSIT.2004.1345386
