QUANTUM CELLULAR AUTOMATA
Theory, Experimentation and Prospects
CONTENTS
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FRONT MATTER
| i |
The Concept of Quantum-Dot Cellular Automata
Craig S. Lent | 1 |
QCA Simulation with the Occupation-Number Hamiltonian
Massimo Macucci and Michele Governale | 17 |
Realistic Time-Independent Models of a QCA Cell
Joan Martorell, Donald W. L. Sprung, Michele Girlanda and Massimo Macucci | 25 |
Time-Independent Simulation of QCA Circuits
Luca Bonci, Sandro Francaviglia, Mario Gattobigio, Carlo Ungarelli, Giuseppe Iannaccone and Massimo Macucci | 65 |
Simulation of the Time-Dependent Behavior of QCA Circuits with the Occupation-Number Hamiltonian
Irina Yakimenko and Karl-Fredrik Berggren | 87 |
Time-Dependent Analysis of QCA Circuits with the Monte Carlo Method
Luca Bonci, Mario Gattobigio, Giuseppe Iannaccone and Massimo Macucci | 109 |
Implementation of QCA Cells with SOI Technology
Freek E. Prins, Christof Single, Gregor Wetekam, Dieter P. Kern, Massimo Macucci, Luca Bonci, Giuseppe Iannaccone and Mario Gattobigio | 143 |
Implementation of QCA Cells in GaAs Technology
Yong Jin, Charles G. Smith, Joan Martorell, Donald W. L. Sprung, P. A. Machado, Michele Girlanda, Michele Governale, Giuseppe Iannaccone and Massimo Macucci | 179 |
Non-Invasive Charge Detectors
Giuseppe Iannaccone, Carlo Ungarelli, Michele Governale, Massimo Macucci, Spiros Gardelis, Charles G. Smith, John Cooper, David A. Ritchie, Edmund H. Linfield and Yong Jin | 213 |
Metal Dot QCA
Gregory L. Snider, Alexei O. Orlov and Ravi K. Kummamuru | 229 |
Molecular QCA
Craig S. Lent | 255 |
Magnetic Quantum-Dot Cellular Automata (MQCA)
Alexandra Imre, György Csaba, Gary H. Bernstein and Wolfgang Porod | 269 |
Final Remarks and Future Perspectives
Massimo Macucci | 277 |
BACK MATTER
| 281 |
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