Title :
Simulation of Quantum Transport in Ballistic Double-Gate MOSFETs using Transfer Matrix Method
Author :
Abdolkader, T.M.
Author_Institution :
Benha Higher Inst. of Technol.
Abstract :
Numerical simulation of nanoscale double gate MOSFET depends mainly on the accurate representation of quantum-mechanical effects. These effects include, mainly, the quantum confinement of carriers by gate-oxides in the direction normal to the interfaces, and the quantum transport of carriers along the channel. In a previous work, the use of transfer matrix method (TMM) was proposed for the simulation of the first effect. In this work, TMM is proposed to be used for the solution of Schrodinger equation with open boundary conditions to simulate the second quantum-mechanical effect. Transport properties such as transmission probability, carrier concentration, and I-V characteristics resulting from quantum transport simulation using TMM are compared with that using the traditional tight-binding model (TBM). Comparison showed that, when the same mesh size is used in both methods, TMM gives more accurate results than TBM
Keywords :
MOSFET; nanoelectronics; numerical analysis; quantum theory; transfer function matrices; Schrodinger equation; ballistic double-gate MOSFETs; gate-oxides; nanoscale double gate MOSFET; numerical simulation; open boundary conditions; quantum carrier confinement; quantum transport simulation; quantum-mechanical effects; transfer matrix method; Boundary conditions; Eigenvalues and eigenfunctions; Integrated circuit technology; MOSFETs; Nanoscale devices; Potential well; Predictive models; Schrodinger equation; Solid modeling; Very large scale integration;
Conference_Titel :
Computer Engineering and Systems, The 2006 International Conference on
Conference_Location :
Cairo
Print_ISBN :
1-4244-0271-9
Electronic_ISBN :
1-4244-0272-7
DOI :
10.1109/ICCES.2006.320431
