Polycrystalline-silicon (poly-Si) gate compatibility issues with HfO2 and Al2O3 capped HfO2 gate dielectrics are reported. It can be generally stated that chemical vapor deposition (CVD) silicon gates using silane deposited directly onto HfO2 results in electrical properties much worse compared to similar HfO2 films using platinum metal gates. However, depositing CVD silicon gates directly onto Al2O3 capped HfO2 showed greater than a 104 times reduction in gate leakage compared to the poly-Si/HfO2 and poly-Si/SiO2 controls of similar electrical thickness.
This paper compares the performance and inter-die variability of doped and undoped channel Multiple-Gate FETs (MUGFETs) with respect to planar SOI devices. We show that doped-channel FinFETs have equivalent variability to narrowwidth planar devices. As such, transitions to FinFETs for narrow-width devices will likely incur minimal variability impact. To match the low variability of wide-width planar devices, conversions to undoped channel FinFETs will be necessary. Furthermore, good short-channel control has to be maintained since undoped channel devices exhibit increase sensitivity to T body relative to doped channel FinFETs due to enhanced fully-depleted channel electrostatics.
We report a CMOS-compatible embedded siliconcarbon (eSiC) source/drain stressor technology with NMOS performance enhancement. The integration includes up to 2.6% substitutional carbon (Csub) epitaxial Si:C and laser spike annealing (LSA) for increased Csub incorporation. 26% channel resistance (Rch) reduction and ll% Idlin-loff enhancement for 0.5% Csub and 60% Rch reduction for 2.2% Csub are demonstrated.
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