Title :
Comparisons of Performance Potentials of Silicon Nanowire and Graphene Nanoribbon MOSFETs Considering First-Principles Bandstructure Effects
Author :
Tsuchiya, Hideaki ; Ando, Haruki ; Sawamoto, Shun ; Maegawa, Tadashi ; Hara, Takeshi ; Yao, Hironobu ; Ogawa, Matsuto
Author_Institution :
Kobe Univ., Kobe, Japan
Abstract :
In this paper, we investigate the performance potentials of silicon nanowire (SNW) and semiconducting graphene nanoribbon (GNR) MOSFETs by using first-principles bandstructures and ballistic current estimation based on the ¿top-of-the-barrier¿ model. As a result, we found that SNW-MOSFETs display a strong orientation dependence via the atomistic bandstructure effects, and SNW-MOSFETs provide smaller intrinsic device delays than Si ultrathin-body MOSFETs when the wire size is scaled smaller than 3 nm. Furthermore, GNR-MOSFETs are found to exhibit promising device performance if the ribbon width is designed to be larger than a few nanometers and a finite band gap can be established.
Keywords :
MOSFET; elemental semiconductors; energy gap; graphene; nanowires; silicon; GNR MOSFET; SNW; atomistic band-structure effects; ballistic current estimation; band gap; finite band gap; first-principles bandstructure effects; graphene nanoribbon MOSFET; intrinsic device; silicon nanowire; top-of-the-barrier model; ultrathin-body MOSFET; wire size; Delay effects; Displays; Electron mobility; Leakage current; MOSFETs; Photonic band gap; Semiconductivity; Silicon; Tunneling; Wire; Ballistic transport; bandstructure; first-principles calculation; graphene nanoribbon (GNR); nanotransistors; silicon nanowire (SNW);
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2009.2037365
