NBTI and PBTI are studied in IL/HK/MG gate stacks having EOT down to ∼ 6Å and fabricated using low T RTP based thermal IL and a novel IL/HK integration. At equivalent EOT, proposed stacks provide improved NBTI and similar PBTI when compared to conventional Chem-Ox IL based HKMG stacks. EOT scaling achieved by RTP thermal IL scaling shows lower rate of increase in NBTI and PBTI when compared to Chem-Ox IL scavenged stacks. Impact of Nitrogen and role of post HK nitridation are studied. Physical mechanism of improved BTI in proposed stacks is discussed in detail.
The transition from a planar to a FinFET device structure has changed device doping requirements. The fin sidewall doping and activation, crystallinity control of the fin, junction profile and leakage control on the fin are new challenges. With continuous scaling of FinFET technology, the narrower fins become more prone to crystallinity damage by ion implant, and lead to increases in junction leakage and fin parasitic resistance. We have introduced hot implant as a superior doping technique to room-temperature implant for arsenic source drain extension (SDE) and halo implants on vertical narrow fins. We have demonstrated for the first time that hot SDE implant on 6nm CD vertical fins produced single crystalline fins and enabled 5x improvement in fin line resistance and more than 10x reduction in junction leakage compared with a room-temperature SDE implant.
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