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scale. As technology limits are being reached, it may be such disruptive technologies
that enable us to build the future generations of computer technology.
REFERENCES
1. ITRS. International Technology Roadmap for Semiconductors (ITRS): Emerging
Research Devices. 2006.
2. C. S. Lent, P. D. Tougaw, W. Porod, and G. H. Bernstein. Quantum Cellular
Automata. Nanotechnology, 4: pp 49-57, 1993.
3. M. Macucci, M. Gattobigio, L. Bonci, G. Iannaccone, F. E. Prins, C. Single, G.
Wetekam, and D. P. Kern. A QCA cell in silicon-on-insulator technology: theory and
experiment. Superlattices and Microstructures, 34: pp 205-211, 2003.
4. H. C. Jared, D. G. Andrew, J. W. Cameron, C L H Lloyd, and P. Steven. Quantum-dot
cellular automata using buried dopants, Physical Review B, 71: p 115302, 2005.
5. M. Mitic, M. C. Cassidy, K. D. Petersson, R. P. Starrett, E. Gauja, R. Brenner, R. G.
Clark, A. S. Dzurak, C. Yang, and D. N. Jamieson. Demonstration of a silicon-based
quantum cellular automata cell. Applied Physics Letters, 89: p 013503, 2006.
6. A. O. Orlov, I. Amlani, G. H. Bernstein, C. S. Lent, and G. L. Snider. Realization of a
functional cell for quantum-dot cellular automata. Science, 277: pp 928-930, 1997.
7. I. Amlani, A. O. Orlov, G. L. Snider, C. S. Lent, and G. H. Bernstein. Demonstration
of a functional quantum-dot cellular automata cell. Journal of Vacuum Science and
Technology B, 16: pp 3795-3799, 1998.
8. I. Amlani, A. O. Orlov, G. L. Snider, C. S. Lent, and G. H. Bernstein. Demon-
stration of a six-dot quantum cellular automata system. Applied Physics Letters, 72: pp
2179-2181, 1998.
9. G. L. Snider, A. O. Orlov, I. Amlani, G. H. Bernstein, C. S. Lent, J. L. Merz, and
W. Porod. Experimental demonstration of quantum-dot cellular automata. Semicon-
ductor Science and Technology, 13: pp A130-A134, 1998.
10. G. L. Snider, O. Orlov, I. Amlani, G. H. Bernstein, C. S. Lent, J. L. Merz, and
W. Porod. A functional cell for quantum-dot cellular automata. Solid-State Electronics,
42: pp 1355-1359, 1998.
11. I. Amlani, A. O. Orlov, G. L. Snider, C. S. Lent, W. Porod, and G. H. Bernstein.
Experimental demonstration of electron switching in a quantum-dot cellular automata
(QCA) cell. Superlattices and Microstructures, 25: pp 273-278, 1999.
12. I. Amlani, A. O. Orlov, G. Toth, G. H. Bernstein, C. S. Lent, and G. L. Snider. Digital
logic gate using quantum-dot cellular automata. Science, 284: pp 289-291, 1999.
13. G. H. Bernstein, I. Amlani, A. O. Orlov, C. S. Lent, and G. L. Snider. Observation of
switching in a quantum-dot cellular automata cell. Nanotechnology, 10: pp 166-173, 1999.
14. A. O. Orlov, I. Amlani, G. Toth, C. S. Lent, G. H. Bernstein, and G. L. Snider.
Experimental demonstration of a binary wire for quantum-dot cellular automata.
Applied Physics Letters, 74: pp 2875-2877, 1999.
15. W. Porod, C. S. Lent, G. H. Bernstein, A. O. Orlov, I. Amlani, G. L. Snider, and J. L.
Merz. Quantum-dot cellular automata: computing with coupled quantum dots.
International Journal of Electronics, 86: pp 549-590, 1999.
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