Performance Evaluation of Junctionless Cylindrical Gate-All-Around FET for Low Power Applications

Abstract

The advent of device miniaturization techniques and the evolution of very deep submicron technology have led to the increased prominence of short channel effects (SCEs) in conventional transistors (CTs). Now, in the era of nanoengineering and nano-wires, current research is centered around a novel device known as the Junctionless Field Effect Transistor (JLFET), which incorporates gate-all-around engineering applications. Given the challenges associated with scaling transistor sizes, such as creating high-quality junctions and changing doping concentrations (~1019 cm–3) over a 10 nm distance, JLFET emerges as a promising alternative to CTs. Notably, JLFET lacks junctions and doping concentration gradients. In this study, the authors have conducted a comprehensive analysis and performance evaluation of JLFET and CTs, specifically in the context of low-power applications. Various performance parameters of JLFET, including SS, DIBL, transconductance, output conductance, and Ion/Ioff, have been assessed. The findings indicate that JLFET exhibits reduced susceptibility to SCEs compared to CTs and demonstrates exceptional current driving capability.