Analysis of the Impact of Process Variations and Manufacturing Defects on the Performance of Carbon-Nanotube FETs
Sanmitra Banerjee, Arjun Chaudhuri, Krishnendu Chakrabarty
Abstract
Carbon-nanotube FETs (CNFETs) are potential successors to CMOS transistors; these emerging devices have a low intrinsic delay due to near-ballistic transport in carbon nanotubes (CNTs). As CNFETs are evaluated for circuit/system design, it is important to analyze variations in CNT process parameters. In this article, we present a systematic approach to quantify the impact of these imperfections on the transistor- and gate-level performances of CNT-based circuits. Process variations are investigated to identify the critical device parameters that have maximum impact on the device on-current. We also present a model that predicts the realistic CNFET yield in the presence of process variations. Finally, the impact of manufacturing defects, such as pinholes in the gate dielectric and parasitic CNFETs formed due to imperfect etching, are modeled and evaluated using HSPICE.