Exploring the Performance of 3-D Nanosheet FET in Inversion and Junctionless Modes: Device and Circuit-Level Analysis and Comparison

V. Bharath Sreenivasulu, Aruna Kumari Neelam, Sekhar Reddy Kola, Jawar Singh, Yiming Li*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

18 Scopus citations

Abstract

In this article, the performance of 3-D nanosheet FET (NS-FET) in inversion (INV) and junctionless (JL) modes is demonstrated and compared at both device and circuit levels. In JL mode, the ON current ( ION ) rises with an increase in temperature compared to the downfall trend in INV mode. In addition, compared to JL mode, the INV mode exhibits a better negative temperature coefficient of threshold voltage (dVth /dT). Further, the mixed mode circuit simulations are carried out using the Cadence Virtuoso platform through the Verilog-A model. From the analysis, it is observed that an increase of 20% gain in INV mode compared to JL mode for a common source (CS) amplifier. The JL mode NS-FETs achieve higher CMOS inverter switching current ( ISC ) and lower energy-delay products (EDP) as temperature rises. A three-stage ring oscillator (RO) is designed, and the oscillation frequencies ( fOSC ) of 43.39 GHz and 38.8 GHz are obtained with INV and JL modes. Although JL NS-FET offers less intrinsic capacitances, the fOSC is high for INV mode due to higher ION. Furthermore, reducing supply voltage ( VDD ), the fOSC falls by 67% with INV and 62.6% with JL modes. These results will give a better understanding of this emerging NS-FET at both device and circuit levels at advanced technology nodes.

Original languageEnglish
Pages (from-to)90421-90429
Number of pages9
JournalIEEE Access
Volume11
DOIs
StatePublished - 2023

Keywords

  • CMOS inverter
  • CS amplifier
  • Verilog-A
  • inversion
  • junctionless
  • nanosheet FET
  • ring oscillator

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