Title :
High performance double gate silicon nanowire transistors
Author :
Sagana Gandi, M. ; Karthigai Pandian, M. ; Balamurugan, N.B.
Author_Institution :
Pandian Saraswathi Yadav Eng. Coll., Sivagangai, India
Abstract :
This paper deals with the study of modelling double gate silicon nanowire transistors. The scaling of nanowire transistors to 10nm and below is discussed for acceptable short-channel effects and the quantum mechanical effects caused by ultrathin silicon devices considered in modelling the threshold voltage is studied. Similarly, the variation of threshold voltage with different doping density, channel length, channel thickness and oxide thickness of DG MOSFET are analysed. The inversion charge and electrical potential along the channel of double gate MOSFET are also discussed in this paper. These approaches analysed are based upon the analytical solutions of Schrödinger and Poisson equations solved in the silicon channel. The simulation results obtained from various methodologies are compared to analyze the performance of the DG MOSFETs.
Keywords :
MOSFET; Poisson equation; Schrodinger equation; electric potential; nanowires; quantum theory; semiconductor device models; semiconductor doping; silicon; Poisson equations; Schrodinger equations; Si; channel length; channel thickness; doping density; double gate MOSFET; double gate silicon nanowire transistors; electrical potential; inversion charge; oxide thickness; quantum mechanical effects; scaling; short-channel effects; threshold voltage; ultrathin silicon devices; Equations; Logic gates; MOSFET; Mathematical model; Nanoscale devices; Semiconductor process modeling; Double Gate (DG); Electric potential; Inversion-charge; Quantum Mechanical Effects (QME); Scaling; Short Channel Effects (SCE); Silicon Nanowire Transistor (SiNW); Threshold voltage;
Conference_Titel :
Emerging Trends in VLSI, Embedded System, Nano Electronics and Telecommunication System (ICEVENT), 2013 International Conference on
Conference_Location :
Tiruvannamalai
Print_ISBN :
978-1-4673-5300-7
DOI :
10.1109/ICEVENT.2013.6496585
