The NCN: Science, simulation, and cyber services

NanoSingapore 2006: IEEE Conference on Emerging Technologies - Nanoelectronics - Proceedings

Volumn 2006, Issue , 2006, Pages 496-500

  Lundstrom, Mark ^a   Klimeck, Gerhard ^a  

^a Purdue University   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

COMPUTATIONAL METHODS; COMPUTER AIDED DESIGN; COMPUTER SIMULATION; CYBERNETICS; ENGINEERING EDUCATION; NANOTECHNOLOGY;

COMPUTATIONAL NANOTECHNOLOGY; COMPUTATIONAL RESEARCHES; CYBERINFRACTURES; NANOCURRICULUM;

COMPUTER NETWORKS;

EID: 33750828922     PISSN: None     EISSN: None     Source Type: Conference Proceeding    
DOI: 10.1109/NANOEL.2006.1609779     Document Type: Conference Paper

References (15)

1. Leo P. Kadanoff, "Excellence in Computer Simulation," Computing in Science and Engineering, pp. 57-67, March/April 2004. (available at http://jfi.uchicago.edu/~leop/SciencePapers/Spapers.html)
2. Leo P. Kadanoff, "Computational Scenarios," Reference Frame, in Physics Today, pp. 10, 11, November, 2004. (available at http://jfi.uchicago. edu/~leop/SciencePapers/Spapers.html)
3. Ian Foster, "Service-Oriented Science," Science, 308, May 6, 2005.
4. J.A.B. Fortes, R.J. Figueiredo, and M.S. Lundstrom, "Virtual Computing Infrastructures for Nanoelectronics Simulation," Proc. IEEE, 93, pp. 1839-1847, 2005.
5. S. Datta, "Nanoscale Device Simulation: The Green's Function Formalism", Superlattices and Microstructures, 28, 253-278(2000).
6. F. Zahid, A. W. Ghosh, M. Paulsson, E. Polizzi and S. Datta, "Charging-induced asymmetry in molecular conductors", Phys. Rev. B, 70, 245317 (2004).
7. T. Rakshit, G.C. Liang, A.W. Ghosh, S. Datta, "Silicon-based Molecular Electronics", Nano Lett., 4, 1083 (2004).
8. Avik W. Ghosh, Titash Rakshit, and Supriyo Datta, "Gating of a Molecular Transistor:Electrostatic and Conformational", Nano Lett.; 4(4), 565-568; (2004).
9. A.W. Ghosh, P.S. Damle, S. Datta, and A. Nitzan, "Molecular Electronics: Theory and Device Prospects", MRS Bulletin, 29, 391 (2004).
10. Jing Guo, Supriyo Datta, Mark Lundstrom, and M.P. Anantram, "Towards Multi-Scale Modeling of Carbon Nanotube Transistors," International J. on Multiscale Computational Engineering, special issue on multiscale methods for emerging technologies, N. Aluru, editor, 2, pp. 257-276. (2004).
11. R. Venugopal, S. Goasguen, S. Datta, and M.S. Lundstrom, "A Quantum Mechanical Analysis of Channel Access, Geometry and Series Resistance in Nanoscale Transistors," J. Appl. Physics, 95, pp. 292-305, (2004).
12. S. Datta, Quantum Transport: From Atom to Transistor, Cambridge University Press, Cambridge, U.K., 2005.
13. Zhibin Ren, Ramesh Venugopal, Sebastien Goasguen, Supriyo Datta, and Mark S. Lundstrom "nanoMOS 2.5: A Two -Dimensional Simulator for Quantum Transport in Double-Gate MOSFETs," IEEE Trans. Electron. Dev., 50, pp. 1914-1925, (2003).
14. José A.B. Fortes, Renato J. Figueirdo, and Mark S. Lundstrom, "Virtual Computing Infrastructures for Nanoelectronics Simulation," Proc. IEEE, 93, pp. 1839-1847, Oct., 2005.
15. Nirav H. Kapadia, Jose A.B. Fortes, and Mark S. Lundstrom, "The Purdue University Network-Computing Hubs: Running Unmodified Simulation Tools via the WWW," ACM Trans. On Modeling and Computer Simulation, pp. 1-19, 2001.