| Preface | |
| Introductory Concepts | p. 3 |
| Multiparticle Interferometry and the Superposition Principle | p. 4 |
| Quantum Entanglement: A Fundamental Concept Finding its Applications | p. 12 |
| Experiment and the Foundations of Quantum Physics | p. 19 |
| Quantum Entanglement Manipulation | p. 31 |
| Teleporting an Unknown Quantum State via Dual Classic and Einstein-Podolsky-Rosen Channels | p. 35 |
| Experimental Quantum Teleportation | p. 40 |
| Teleportation of Continuous Quantum Variables | p. 45 |
| Going Beyond Bell's Theorem in Bell's Theorem, Quantum Theory and Conception of the Universe | p. 49 |
| What Is Wrong with These Elements of Reality | p. 53 |
| Observation of Three-Photon Greenberger-Horne-Zeilinger Entanglement | p. 55 |
| Quantum Algorithms | p. 63 |
| An Overview of Quantum Computing | p. 66 |
| On Quantum Algorithms | p. 86 |
| An Introduction to Quantum Complexity Theory | p. 103 |
| Quantum Error Correction | p. 131 |
| Scheme for Reducing Decoherence in Quantum Computer Memory | p. 134 |
| Error Correcting Codes in Quantum Theory | p. 138 |
| Class of Quantum Error-Correcting Codes Saturating the Quantum Hamming Bound | p. 143 |
| Fault-Tolerant Error Correction with Efficient Quantum Codes | p. 150 |
| Quantum Channels | p. 157 |
| General Scheme of Measurement Processes | p. 161 |
| Completely Positive Linear Maps on Complex Matrices | p. 174 |
| Sending Entanglement Through Noisy Quantum Channels | p. 180 |
| Noncommuting Mixed States Cannot Be Broadcast | p. 195 |
| Sending Classical Information via Noisy Quantum Channels | p. 199 |
| Nonorthogonal Quantum States Maximize Classical Information Capacity | p. 207 |
| Long-Distance Quantum Communication | p. 213 |
| Quantum Repeaters: The Role of Imperfect Local Operations in Quantum Communication | p. 217 |
| Purification of Noisy Entanglement and Faithful Teleportation via Noisy Channels | p. 221 |
| Quantum Privacy Amplification and the Security of Quantum Cryptography over Noisy Channels | p. 225 |
| Photonic Channels for Quantum Communication | p. 229 |
| Quantum Key Distribution | p. 235 |
| Quantum Cryptography | p. 240 |
| Practical Aspects of Quantum Cryptographic Key Distribution | p. 245 |
| Quantum Key Distribution: From Principles to Practicalities in Applicable Algebra in Engineering, Communication and Communication | p. 259 |
| Cavity Quantum Electrodynamics | p. 277 |
| Cavity Quantum Electrodynamics | p. 282 |
| Measurement of Conditional Phase Shifts for Quantum Logic | p. 290 |
| Real-Time Cavity QED with Single Atoms | p. 294 |
| Quantum Memory with a Single Photon in a Cavity | p. 298 |
| Observing the Progressive Decoherence of the "Meter" in a Quantum Measurement | p. 302 |
| Inversion of Quantum Jumps in Quantum Optical Systems under Continuous Observation | p. 306 |
| Quantum Computation with Ion Traps | p. 313 |
| Electromagnetic Traps for Charged and Neutral Particles | p. 320 |
| Quantum Computations with Cold Trapped Ions | p. 330 |
| New Ion Trap for Frequency Standard Applications | p. 334 |
| Ion Strings for Quantum Gates | p. 339 |
| Quantum Dynamics of Cold Trapped Ions with Application to Quantum Computation | p. 345 |
| Demonstration of a Fundamental Quantum Logic Gate | p. 355 |
| Deterministic Entanglement of Two Trapped Ions | p. 359 |
| Josephson Junctions and Quantum Computation | p. 365 |
| Mesoscopic Effects in Superconductivity in Mesoscopic Electron Transport | p. 368 |
| Quantum Manipulations of Small Josephson Junctions | p. 391 |
| Josephson-Junction Qubits with Controlled Couplings | p. 395 |
| Quantum Information in Optical Lattices | p. 401 |
| Quantum Computing with Neutral Atoms | p. 404 |
| Quantum Computation and Quantum Communication with Electrons | p. 427 |
| Quantum Computation with Quantum Dots | p. 433 |
| Coupled Quantum Dots as Quantum Gates | p. 440 |
| Quantum Computers and Quantum Coherence | p. 449 |
| Quantum Computing with NMR | p. 465 |
| Nuclear Magnetic Resonance Spectroscopy: An Experimentally Accessible Paradigm for Quantum Computing | p. 471 |
| Implementation of a Quantum Algorithm on a Nuclear Magnetic Resonance Quantum Computer | p. 476 |
| Experimental Implementation of Fast Quantum Searching | p. 482 |
| An Implementation of the Deutsch-Jozsa Algorithm on a Three-Qubit NMR Quantum Computer | p. 486 |
| Selected Bibliography | p. 493 |
| Table of Contents provided by Blackwell. All Rights Reserved. |
