Tuesday, October 26, 12:30 p.m. - 3:00 p.m.
Rooms 302/306, Stewart Center with lunch
All abstracts are PDFs and can be read with Adobe Acrobat Reader.
[Quantum Transport] •
[Molecular/Organic] •
[Alternative Computing] •
[Optical]
|
Quantum Transport
|
01 |
Simulation Schemes in 2D Nanoscale MOSFET's: WKB Based Method
N.B. Abdallah, C. Negulescu, M. Mouis, and E. Polizzi
• abstract
Universitè Paul Sabatier |
02 |
Quantum Potential Approach to Modeling Nano-MOSFETs
S.S. Ahmed, C. Ringhofer, and D. Vasileska
• abstract
Arizona State University |
03 |
Vortex Flows in Semiconductor Device Quantum Channels: Time-Dependent Simulation
J. Barker and A. Martinez
• abstract
University of Glasgow |
04 |
Simulation of Entanglement Dynamics for a Scattering between a Free and a Bound Carrier in a Quantum Wire
P. Bordone, A. Bertoni, and C. Jacoboni
• abstract
Università di Modena e Reggio Emilia |
05 |
Wigner Function for Identical Particles
E. Cancellieri, P. Bordone, A. Bertoni, G. Ferrari, and C. Jacoboni
• abstract
Università di Modena e Reggio Emilia |
06 |
Spectral Element Method for the Schrödinger-Poisson System
C. Cheng, Q.H. Liu, and H.Z. Massoud
• abstract
Duke University |
07 |
Code for the 3D Simulation of Nanoscale Semiconductor Devices, including Drift-Diffusion and Ballistic Transport in 1D and 2D Subbands, and 3D Tunneling
G. Fiori and G. Iannaccone
• abstract
Università degli studi di Pisa |
08 |
Modeling of Inelastic Transport in One-Dimensional Metallic Atomic Wires
T. Frederiksen, M. Brandbyge, N. Lorente, and A.-P. Jauho
• abstract
Technical University of Denmark and Université Paul Sabatier |
09 |
Wigner-Function Based Simulation of Classic and Ballistic Transport in Scaled DG-MOSFETs using the Monte Carlo Method
A. Gehring and H. Kosina
• abstract
Institute of Microelectronics |
10 |
On the Electrostatics of Double-Gate and Cylindrical Nanowire MOSFETs
E. Gnani, S. Reggiani, M. Rudan, and G. Baccarani
• abstract
University of Bologna |
11 |
High-Resolution Numerical Study of Conductance and Noise Imaging of Mesoscopic Devices
M. Macucci and P. Marconcini
• abstract
Università degli Studi di Pisa |
12 |
A Critical Examination of the Basis of Macroscopic Quantum Transport Approaches
V. Narayanan and E.C. Kan
• abstract
Cornell University |
13 |
Numerical Simulation for Direct Tunneling Current in Poly-Si-Gate MOS Capacitors
M. Okamoto and N. Mori
• abstract
Osaka University |
14 |
Numerical Analysis of Coaxial Double Gate Schotttky Barrier Carbon Nanotube Field Effect Transistors
M. Pourfath, E. Ungersboeck, A. Gehring, W.J. Park, B.H Cheong, H. Kosina, and S. Selberherr
• abstract
Institute of Microelectronics and Samsung Advanced Institute of Technology |
15 |
Examination of Boundary Effects of Resonant Tunneling Structures using Lattice Weyl-Wigner Transport Simulations
G. Recine, B. Rossen, and H.L. Cui
Stevens Institute of Technology |
16 |
Single Electron Transport and Entanglement Induced by a Surface Acoustic Waves versus Free Ballistic Propagation in Coupled Quantum Wires
M. Rosini, A. Bertoni, P. Bordone, and C. Jacoboni
• abstract
Dipartimento di Ingegneria dell'Innovazione, INFM-S3 Research Centre, and Università di Modena e Reggio Emilia |
17 |
Quantum Lattice-Gas Automata Simulation of Electronic Wave Propagation in Nanostructures
A. Sakai, Y. Kamakura, and K. Taniguchi
• abstract
Osaka University |
18 |
From Wave-Functions to Current-Voltage Characteristics in Silicon Single Nanocyrstal Coulomb Blockade Devices
J. Sée, P. Dollfus, S. Galdin, and P. Hesto
• abstract
Université Paris-Sud |
19 |
A High Order Local Solver for Wigner Equation
J. Shi and I.M. Gamba
• abstract
The University of Texas at Austin |
20 |
A Microscopic Quantum Simulation
of Si/SiO2 Interface Roughness Scattering in Silicon Nanowire Transistors
J. Wang, E. Polizzi, A. Ghosh, S. Datta, and M. Lundstrom
• abstract
Purdue University |
Molecular/Organic
|
21 |
Atomistic Treatment of Nanotube-Metal Interfaces
D. Kienle, A. Ghosh, and M. Lundstrom
• abstract
Purdue University |
22 |
Electronic Transport in Discotic Liquid Crystal Columns
L. Lever, R.J. Bushby, and R.W. Kelsall
• abstract
University of Leeds |
23 |
Hybrid- Basis Modeling of Electron Transport through Molecules on Silicon
G. Liang, A Ghosh, T. Rakshit, and S. Datta
• abstract
Purdue University |
Alternative Computing Architectures
|
24 |
Theoretical Evidence of Spontaneous Spin Polarization in GaAs/AlGaAs Split- Gate Heterostructures
A. Ashok, R. Akis, D. Vasileska, and D.K. Ferry
• abstract
Arizona Sate University |
25 |
Fano Resonances through Quantum Dots in Tunable Aharonov-Bohm Rings
Y.S Joe, J.S., Kim E.R. Hedin, R.M. Cosby, and A.M. Satanin
• abstract
Ball State University |
26 |
Computer Simulation of Magnetization for Vertically Coupled Nanoscaole Quantum Rings
Y. Li
• abstract
National Chiao Tung University |
27 |
Modeling of the Electrostatic (Plasmon) Resonances In Metallic and Semiconductor Nanoparticles
I.D. Mayergoyz and Z. Zhang
• abstract
University of Maryland |
28 |
Resonance Spin Filter
B.S. Pavlov and A.M. Yafyasov
St. Petersburg State University and University of Auckland |
29 |
Hilbert Graph: An Expandable Interconnection for Clusters
F.Rodríguez-Salazar and J.R. Barker
• abstract
University of Glasgow |
30 |
Manipulating of Resonances in Conductance of an Electron Waveguide with Antidots
A.M Satanin and Y.S. Joe
• abstract
Ball State University |
Optical
|
31 |
On the Formation of Periodic Electric Field Domains in p-Si/SiGe Quantum Dots in Cascade Structures
Z. Ikonic, P. Harrison, and R.W. Kelsall
• abstract
University of Leeds |
32 |
Three-Dimensional Finite-Difference Time-Domain Simulation of Facet Reflection through Parallel Computing
D. Labukhin and X. Li
• abstract
McMaster University |
33 |
Tunable Optical Properties of Colloidal Quantum Dots in Electrolytic Environments
M.A. Stroscio, M. Dutta, D.Ramadurai, B. Kohanpour, D. Alexson, P. Shi, A. Sethuraman, Y. Li, and V. Saini
• abstract
University of Illinois at Chicago |
34 |
Electronic Structure and Optical Transitions in InAsSb/InGaAs Quantum Dots
P. von Allmen, S. Lee, and F. Oyafuso
• abstract
California Institute of Technology |