Scaling challenges and device design requirements for high performance sub-50 nm gate length planar CMOS transistors

Summary form only given. We investigate scaling challenges and outline device design requirements needed to support high performance-low power planar CMOS transistor structures with physical gate lengths (L/sub GATE/) below 50 nm. This work uses a combination of simulation results, experimental data and critical analysis of published data. A realistic assessment of gate oxide thickness scaling and maximum tolerable oxide leakage is provided. We conclude that the commonly accepted upper limit of 1 A/cm/sup 2/ for gate leakage is overly pessimistic and that leakage values of up to 100 A/cm/sup 2/ are deemed acceptable for future logic technology generations. Unique channel mobility and junction edge leakage degradation mechanisms, which become prominent at 50 nm L/sub GATE/ dimensions, are highlighted using quantitative analysis. Source-drain extension (SDE) profile design requirements to simultaneously minimize short channel effects (SCE) and achieve low parasitic resistance for sub-50 nm L/sub GATE/ transistors are described for the first time.