Title :
A Semiphysical Large-Signal Compact Carbon Nanotube FET Model for Analog RF Applications
Author :
Schroter, Michael ; Haferlach, Max ; Pacheco-Sanchez, Anibal ; Mothes, Sven ; Sakalas, Paulius ; Claus, Martin
Author_Institution :
Dept. of Electr. & Comput. Eng., Tech. Univ. Dresden, Dresden, Germany
Abstract :
A compact large-signal model, called Compact Carbon Nanotube Model (CCAM), is presented that accurately describes the shape of DC and small-signal characteristics of fabricated carbon nano-tube FETs (CNTFETs). The new model consists of computationally efficient and smooth current and charge formulations. The model allows, for a given gate length, geometry scaling from single-finger single-tube to multifinger multitube transistors. Ambipolar transport, temperature dependence with self-heating, noise, and a simple trap model have also been included. The new model shows excellent agreement with the data from both the Boltzmann transport equation and measurements of Schottky-barrier CNTFETs and has been implemented in Verilog-A, making it widely available across circuit simulators.
Keywords :
carbon nanotube field effect transistors; semiconductor device models; Boltzmann transport equation; CCAM; Schottky-barrier CNTFET; Verilog-A; ambipolar transport; analog RF applications; carbon nanotube FET; circuit simulators; compact carbon nanotube model; compact large-signal model; gate length; geometry scaling; multifinger multitube transistors; self-heat; simple trap model; single-finger single-tube transistors; temperature dependence; CNTFETs; Capacitance; Electron tubes; Integrated circuit modeling; Logic gates; Mathematical model; Radio frequency; Carbon nanotube field-effect transistor (CNTFET); compact transistor modeling; high-frequency circuit design; high-frequency circuit design.;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2014.2373149
