Title :
Dual Strained Channel co-integration into CMOS, RO and SRAM cells on FDSOI down to 17nm gate length
Author :
Hutin, L. ; Le Royer, C. ; Andrieu, F. ; Weber, O. ; Cassé, M. ; Hartmann, J.-M. ; Cooper, D. ; Béché, A. ; Brévard, L. ; Brunet, L. ; Cluzel, J. ; Batude, P. ; Vinet, M. ; Faynot, O.
Author_Institution :
LETI, CEA, Grenoble, France
Abstract :
We hereby present for the first time a successful Dual Strained Channel On Insulator (DSCOI) planar co-integration of tensily strained SOI nFETs and compressively strained SiGe pFETs down to 17nm gate length with functional ring oscillators and 6T SRAM cells. Various Ge contents and growth templates (unstrained or strained SOI) were screened in order to optimize the trade-off between threshold voltage adjustment with a single metal gate and strain-induced mobility enhancement. In particular, we reach 106% mobility boost for nFETs on sSOI and 70% for co-integrated pFETs on Si0.6Ge0.4/sSOI, compared to SOI (Eeff=0.6MV/cm). Moreover, the symmetrically low Vth,n and Vth,p result in -39% propagation delays improvement compared to SOI at 0.9V supply voltage.
Keywords :
CMOS integrated circuits; SRAM chips; field effect transistors; oscillators; silicon-on-insulator; CMOS cell; FDSOI; RO cell; SOI nFET; SRAM cell; SiGe pFET; dual strained channel co-integration; dual strained channel on insulator; functional ring oscillators; size 17 nm; threshold voltage;
Conference_Titel :
Electron Devices Meeting (IEDM), 2010 IEEE International
Conference_Location :
San Francisco, CA
Print_ISBN :
978-1-4424-7418-5
Electronic_ISBN :
0163-1918
DOI :
10.1109/IEDM.2010.5703338
