Experimental Aspects of Quantum Computing

1. Front Matter

   Pages i-vi

   PDF

2. Introduction

   1. Introduction

      • Henry Everitt

      Pages 1-4

3. Invited Articles

   1. Progress in Quantum Algorithms

      • Peter W. Shor

      Pages 5-13

   2. NMR Quantum Information Processing

      • Chandrasekhar Ramanathan, Nicolas Boulant, Zhiying Chen, David G. Cory, Isaac Chuang, Matthias Steffen

      Pages 15-44

   3. Quantum Computing with Trapped Ion Hyperfine Qubits

      • B. B. Blinov, D. Leibfried, C. Monroe, D. J. Wineland

      Pages 45-59

   4. Ion Trap Quantum Computing with Ca+ Ions

      • R. Blatt, H. Häffner, C. F. Roos, C. Becher, F. Schmidt-Kaler

      Pages 61-73

   5. Quantum Information Processing in Cavity-QED

      • S. J. van Enk, H. J. Kimble, H. Mabuchi

      Pages 75-90

   6. Quantum Information Processing with Trapped Neutral Atoms

      • P. S. Jessen, I. H. Deutsch, R. Stock

      Pages 91-103

   7. The Road to a Silicon Quantum Computer

      • J. R. Tucker, T. -C. Shen

      Pages 105-113

   8. Controlling Spin Qubits in Quantum Dots

      • Hans-Andreas Engel, L. P. Kouwenhoven, Daniel Loss, C. M. Marcus

      Pages 115-132

   9. Spin-based Quantum Dot Quantum Computing in Silicon

      • Mark A. Eriksson, Mark Friesen, Susan N. Coppersmith, Robert Joynt, Levente J. Klein, Keith Slinker et al.

      Pages 133-146

   10. Optically Driven Quantum Computing Devices Based on Semiconductor Quantum Dots

       • Xiaoqin Li, Duncan Steel, Daniel Gammon, L. J. Sham

       Pages 147-161

   11. Implementing Qubits with Superconducting Integrated Circuits

       • Michel H. Devoret, John M. Martinis

       Pages 163-203

   12. Towards Scalable Linear-Optical Quantum Computers

       • J. P. Dowling, J. D. Franson, H. Lee, G. J. Milburn

       Pages 205-213

   13. Photonic Technologies for Quantum Information Processing

       • Prem Kumar, Paul Kwiat, Alan Migdall, Sae Woo Nam, Jelena Vuckovic, Franco N. C. Wong

       Pages 215-231

4. Contributed Articles

   1. Quantum Computer Development with Single Ion Implantation

      • A. Persaud, S. J. Park, J. A. Liddle, I. W. Rangelow, J. Bokor, R. Keller et al.

      Pages 233-245

   2. Bang-Bang Refocusing of a Qubit Exposed to Telegraph Noise

      • Henryk Gutmann, Frank K. Wilhelm, William M. Kaminsky, Seth Lloyd

      Pages 247-272

   3. Quantum Computing and Information Extraction for Dynamical Quantum Systems

      • Giuliano Benenti, Giulio Casati, Simone Montangero

      Pages 273-293

   4. One-Dimensional Continuous-Time Quantum Walks

      • D. ben-Avraham, E. M. Bollt, C. Tamon

      Pages 295-308

Practical quantum computing still seems more than a decade away, and researchers have not even identified what the best physical implementation of a quantum bit will be. There is a real need in the scientific literature for a dialogue on the topic of lessons learned and looming roadblocks. This reprint from Quantum Information Processing is dedicated to the experimental aspects of quantum computing and includes articles that 1) highlight the lessons learned over the last 10 years, and 2) outline the challenges over the next 10 years. The special issue includes a series of invited articles that discuss the most promising physical implementations of quantum computing. The invited articles were to draw grand conclusions about the past and speculate about the future, not just report results from the present.

• Cavity-QED
• NMR quantum information processing
• ion trap quantum computing
• one-dimensional continuous-time quantum walk
• quantum algorithm
• quantum computer
• quantum dot
• quantum system
• qubit
• scalable linear-optical quantum computer
• semiconductor quantum dot
• spin qubit
• superconducting integrated circuit
• trapped ion hyperfine qubits
• trapped neutral atoms

• Army Research Office, Research Triangle Park

  Henry O. Everitt