It has been recognised recently that the strange features of the quantum world could be used for new information transmission or processing functions such as quantum cryptography or, more ambitiously, quantum computing. These fascinating perspectives renewed the interest in fundamental quantum properties and lead to important theoretical advances, such as quantum algorithms and quantum error correction codes. On the experimental side, remarkable advances have been achieved in quantum optics, solid state physics or nuclear magnetic resonance. This book presents the lecture notes of the Les Houches Summer School on 'Quantum entanglement and information processing'. Following the long tradition of the les Houches schools, it provides a comprehensive and pedagogical approach of the whole field, written by renowned specialists.One major goal of this book is to establish connections between the communities of quantum optics and of quantum electronic devices working in the area of quantum computing. When two communities share the same goals, the universality of physics unavoidably leads to similar developments. However, the communication barrier is often high, and few physicists are able to overcome it. This school has contributed to bridge the existing gap between communities, for the benefit of the future actors in the field of quantum computing. The book thus combines introductory chapters, providing the reader with a sufficiently wide theoretical framework in quantum information, quantum optics and quantum circuits physics, with more specialized presentations of recent theoretical and experimental advances in the field. This structure makes the book accessible to any graduate student having a good knowledge of basic quantum mechanics, and extremely useful to researchers.
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Zielgruppe
Quantum mechanics teachers, Researchers and Graduate students.
Weitere Infos & Material
Course 1. Principles of quantum computation (I. Chuang).
Course 2. Mesoscopic state superpositions and decoherence in quantum optics (S. Haroche).
Course 3. Cavity quantum electrodynamics (M. Brune).
Course 4. Quantum optical implementation of quantum information processing (P. Zoller et al.).
Course 5. Quantum information processing in ion traps I (R. Blatt et al.).
Course 6. Quantum information processing in ion traps II (D.J. Wineland).
Course 7. Quantum cryptography with and without entanglement (N. Gisin, N. Brunner).
Course 8. Quantum cryptography: from one to many photons (P. Grangier).
Course 9. Entangled photons and quantum communication (M. Aspelmeyer et al.).
Course 10. Nuclear magnetic resonance quantum computation (J.A. Jones).
Course 11. Introduction to quantum conductors (D.C. Glattli).
Course 12. Superconducting qubits (M.H. Devoret,J.M. Martinis).
Course 13. Superconducting qubits and the physics of Josephson junctions (J.M. Martinis).
Course 14. Josephson quantum bits based on a Cooper pair box (D. Vion).
Course 15. Quantum tunnelling of magnetization in molecular nanomagnets (W. Wernsdorfer).
Course 16. Prospects for strong cavity quantum electrodynamics with superconducting cirquits (S.M. Girvin et al.).
Dalibard, Jean
Jean Dalibard works in the field of atomic physics and quantum optics. His recent activities is centered on the physics of cold quantum gases, in particular Bose-Einstein condensation.
