Title :
DFT Modeling of Bulk-Modulated Carbon Nanotube Field-Effect Transistors
Author :
Latessa, Luca ; Pecchia, Alessandro ; Di Carlo, Aldo
Author_Institution :
Dept. of Electron. Eng., Tor Vergata Univ., Rome
Abstract :
We report density-functional theory (DFT) atomistic simulations of the nonequilibrium transport properties of carbon nanotube (CNT) field-effect transistors (FETs). Results have been obtained within a self-consistent approach based on the nonequilibrium Green´s functions (NEGF) scheme. We show that, as the current modulation mechanism is based on the local screening properties of the nanotube channel, a completely new, negative quantum capacitance regime can be entered by the device. We show how a well-tempered device design can be accomplished in this regime by choosing suitable doping profiles and gate contact parameters. At the same time, we detail the fundamental physical mechanisms underlying the bulk-switching operation, including them in a very practical and accurate model, whose parameters can be easily controlled in order to improve the device performance. The dependence of the nanotube screening properties on the temperature is finally explained by means of a self-consistent temperature analysis
Keywords :
Green´s function methods; SCF calculations; carbon nanotubes; density functional theory; doping profiles; field effect transistors; nanotube devices; semiconductor device models; C; DFT modeling; atomistic simulations; carbon nanotube field-effect transistors; density-functional theory; doping profiles; nonequilibrium Green´s functions; quantum capacitance; self-consistent approach; CNTFETs; Carbon nanotubes; Doping profiles; FETs; Green´s function methods; Mechanical factors; Nanoscale devices; Quantum capacitance; Semiconductor process modeling; Temperature dependence; Carbon nanotube; Green´s function; coherent transport; field-effect transistor; quantum capacitance;
Journal_Title :
Nanotechnology, IEEE Transactions on
DOI :
10.1109/TNANO.2006.886782
