Title :
Full-quantum simulation of heterojunction TFET inverters providing better performance than multi-gate CMOS at sub-0.35V VDD
Author :
Baravelli, E. ; Gnani, Elena ; Gnudi, A. ; Reggiani, S. ; Baccarani, G.
Author_Institution :
ARCES, Univ. of Bologna, Bologna, Italy
Abstract :
Tunnel FETs (TFETs) are promising alternatives to the conventional CMOS technology for steeper-than-60mV/dec subthreshold slopes (SS) required to limit power consumption of integrated circuits [1]. Current challenges for TFET integration into practical circuit applications include reaching acceptable ION levels, suppressing ambipolar effects, improving output characteristics [2], and simultaneously co-integrating optimized n-and p-type devices. All of these issues are carefully taken into account in this work. Device- and circuit-level design of TFET inverters is proposed, based on co-optimized n-and p-type TFETs integrated on the same InAs/ Al0.05Ga0.95Sb platform. A full-band quantum simulation approach is adopted to properly account for quantum effects which strongly influence TFET device, and hence circuit, performance. This advances the state of the art of TFET-based circuit literature, which is mostly based on simplified TCAD models [3], with rare calibrations against atomistic calculations [4].
Keywords :
CMOS integrated circuits; III-V semiconductors; aluminium compounds; gallium compounds; high electron mobility transistors; indium compounds; invertors; semiconductor device models; technology CAD (electronics); InAs-Al0.05Ga0.95Sb; InAs/Al0.05Ga0.95Sb platform; TCAD; TFET integration; calibrations; circuit-level design; device-level design; full-quantum simulation; heterojunction TFET inverters; multigate CMOS; n-type TFET; p-type TFET; power consumption; quantum effects; voltage 0.35 V; CMOS integrated circuits; Capacitance; Decision support systems;
Conference_Titel :
Energy Efficient Electronic Systems (E3S), 2013 Third Berkeley Symposium on
Conference_Location :
Berkeley, CA
DOI :
10.1109/E3S.2013.6705875
