As the minimum VLSI feature size continues to scaie down to the 0.1-0.2-ju.m regime, the need for iow-resistance iocai interconnections wiii become increasingiy critical. Although reduction in the MOSFET channel length will remain the dominant factor in achieving higher circuit performance, existing local interconnection materials will impose greater than acceptable performance limitations. We review the state-of-the-art salicide and polycide processes, with emphasis on work at IBM, and discuss the limitations that pertain to future implementations in high-performance VLSI circuit applications. A brief review of various silicide-based and tungsten-based approaches for forming local interconnections is presented, along with a more detailed description of a tungsten-based "damascene" local interconnection approach.
Band-gap engineering using SiGe channels to reduce the threshold voltage (V TH ) in p-channel MOSFETs has enabled a simplified gate-first high-κ/metal gate (HKMG) CMOS integration flow. Integrating Silicon-Germanium channels (cSiGe) on silicon wafers for SOC applications has unique challenges like the oxidation rate differential with silicon, defectivity and interface state density in the unoptimized state, and concerns with T inv scalability. In overcoming these challenges, we show that we can leverage the superior mobility, low threshold voltage and NBTI of cSiGe channels in high-performance (HP) and low power (LP) HKMG CMOS logic MOSFETs with multiple oxides utilizing dual channels for nFET and pFET.Introduction:
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