This project involves numerical simulation of emerging double-gate
(DG) MOSFETs such as FinFET. Internal physical quantities such as
potential/charge distributions as well as terminal DC/AC characteristics
can be obtained from numerical simulations, through which the student will
gain understanding of the device characteristics of these future-generation
device building blocks.
Student: Gu Yu
Iterative Surface Potential Solutions for Double-Gate
MOSFETs
This project involves study of iterative surface-potential solutions
for generic double-gate (DG) and ultra-thin body (UTB) MOSFETs. Based
on the implicit voltage equation of a generic DG MOSFET, surface potentials
can be solved through numerical iteration, which provides useful information
for developing and validating analytical solutions. Through the project,
the student will gain understanding of the device physics of these future-generation
device building blocks.
Student: Wong Gee Soon
2006
Review of Compact Models for Ultra-Thin Body (UTB)
MOSFETs
This project involves a survey of existing analytical compact models
for ultra-thin body (UTB) MOSFETs, which is becoming one of the candidates
for next generation CMOS beyond bulk MOSFETs. Comparison with various
types of MOSFET structures can be made, through which the student will
have a better understanding of the device characteristics and trade-offs.
Student: Ooi Eng Ping
Survey of Future Generation Non-classical MOSFETs
This project involves a survey of future generation non-classical MOSFETs
beyond bulk-CMOS, such as ultra-thin body (UTB) SOI and multiple-gate (double-gate/FinFET,
tri-gate, pi-gate, omega-gate, gate-all-around) MOSFETs. Comparison
among various structures can be made, through which the student will gain
knowledge on future device building blocks.
Student: Tom John
2007