Title :
Noise Modeling of Graphene Resonant Channel Transistors
Author :
Lekas, Michael ; Sunwoo Lee ; Wujoon Cha ; Hone, James ; Shepard, Kenneth
Author_Institution :
Dept. of Electr. Eng., Columbia Univ., New York, NY, USA
Abstract :
In this paper, we present a compact model for graphene resonant channel transistors (G-RCTs) that uses extracted electrical and mechanical parameters to provide an accurate simulation of dc, RF, noise, and frequency-tuning characteristics of the device. The model is validated with measurements on fabricated G-RCTs, which include what we believe to be the first noise measurements conducted on any resonant transistor. The noise model, which considers both electrical and mechanical sources, is used to demonstrate the fundamental differences in the noise behavior of active and passive resonator technologies, and to show how optimization of device parameters can be used to improve the noise performance of RCTs.
Keywords :
graphene devices; noise measurement; resonators; semiconductor device models; C; G-RCT; RF characteristics; active resonator; compact model; dc characteristics; electrical parameters; electrical source; frequency-tuning characteristics; graphene resonant channel transistors; mechanical parameters; mechanical source; noise characteristics; noise measurements; noise modeling; passive resonator; Capacitance; Graphene; Integrated circuit modeling; Logic gates; Mathematical model; Noise; Noise measurement; Compact model; graphene; noise; resonant channel transistor (RCT); resonator; resonator.;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2015.2405540
