Title :
Asymmetric Gate Schottky-Barrier Graphene Nanoribbon FETs for Low-Power Design
Author :
Gholipour, M. ; Masoumi, N. ; Chen, Y.-Y.C. ; Deming Chen ; Pourfath, M.
Author_Institution :
Dept. of Electr. & Comput. Eng., Babol Univ. of Technol., Babol, Iran
Abstract :
The ambipolar behavior limits the performance of Schottky-barrier-type graphene nanoribbon field-effect transistors (SB-GNRFETs). We propose an asymmetric gate (AG) design for SB-GNRFETs, and show that it can significantly reduce the IOFF. Simulation results indicate at least 40% and 5× improvement in the subthreshold swing and the ION/IOFF ratio, respectively. We build an accurate semianalytical closed-form model for the current-voltage characteristics of SB-GNRFETs. The proposed Simulation Program with Integrated Circuit Emphasis (SPICE)-compatible model considering various design parameters and process variation effects, which enables efficient circuit-level simulations of SB-GNRFET-based circuits. Simulation results of benchmark circuits show that the average energy-delay product of the AG SB-GNRFETs is only ~22% of that of a symmetric gate for the ideal case and ~88% for devices with line edge roughness.
Keywords :
Schottky barriers; Schottky gate field effect transistors; circuit simulation; graphene devices; low-power electronics; nanoribbons; semiconductor device models; C; SB-GNRFET; SPICE; Schottky-barrier graphene nanoribbon FET; ambipolar behavior; asymmetric gate design; benchmark circuits; circuit-level simulations; compatible model; current-voltage characteristics; field effect transistors; line edge roughness; low-power design; simulation program with integrated circuit emphasis; subthreshold swing; Graphene; Integrated circuit modeling; Inverters; Logic gates; Photonic band gap; SPICE; Tunneling; Asymmetric gate (AG); Schottky-barrier (SB); Schottky-barrier (SB).; graphene nanoribbon field-effect transistor (GNRFET);
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2014.2362774
