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Research:

Green’s functions for mobility calculation in Low-dimensional systems (Si, GaAs/AlGaAs, InGaAs/InAlAs Q2DEG. For the first time implemented self-consistent Born approximation for the self-energy calculation in transport simulator)

Transport in quantum dots

2D and 3D particle-based device simulators for modeling MOSFETs, DG Devices, FinFETs and FD SOI devices

1D, 2D and 3D self-consistent Schrödinger-Poisson solvers

Quantum effects in ultra-small devices (Proposed novel parameter free Effective potential approach)

Discrete impurity effects in ultra-small devices (First proper treatment of the short-range Coulomb interaction via Molecular Dynamics)

Modeling alternative material systems: strained-Si, strained SiGe, GaN

First self-consistent full-band-Monte Carlo-Poisson-Schrödinger solver for hole transport in SiGe devices

Fastest 3D NEGF solver based on the Contact Block Reduction Method

First self-consistent particle-based solver for modeling Thermal Effects in Nanostructures (solves Boltzmann Transport Equation for electrons self-consistently with energy balance equations for acoustic and optical phonons)

State of the art modeling of GaN HEMTs that includes electromechanical coupling, Coulomb, Quantum and Thermal Effects

Courses Taught at ASU (Available Materials):

ASU101: ASU Experience

EEE/CSE101: Introduction to Engineering Design, EEE101F2008

ECE300: Intermediate Design Project, S2005

ECE301: Electrical Networks I, ECE201F2005

EEE302: Electrical Networks II

EEE202: Electrical Networks I – new course

EEE241: Fundamentals of Electromagnetic Theory

EEE531: Semiconductor Device Theory I

EEE532: Semiconductor Device Theory 2

EEE352: Properties of Electronic Materials