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This book provides the basic knowledge needed to understand and investigate the physics of quantum machines, including quantum superconducting circuits, quantum dots, quantum nanomechanical resonators, trapped ions, single Rydberg atoms in superconducting cavities, and lattices of ultracold atoms.
List of contents
PART I: LECTURES; 1 Hideo Mabuchi: Real-time feedback control of quantum optical input-output systems; 2 Aashish Clerk: Quantum noise and quantum measurement; 3 Steven M. Girvin: Circuit QED: Superconducting qubits coupled to microwave photons; 4 John M. Martinis: Quantum logic gates in superconducting qubits; 5 Immanuel Bloch: Exploring quantum matter with ultracold atoms; 6 Daniel Esteve: Readout of superconducting qubits; 7 Isaac L. Chuang: Quantum error correction; 8 Florian Marquardt: Quantum optomechanics; 9 Konrad W. Lehnert: Micromechanics and superconducting circuits; 10 Amir Yacoby and Hendrik Bluhm: Two electron spin qubits in GaAs: Control and dephasing due to nuclear spins; 11 Jean-Michel Raimond: Exploring the quantum world with photons trapped in cavities and Rydberg atoms; 12 John Clarke, Michel Devoret and Archana Kamal: SQUID amplifiers; 13 Thomas Monz, Philipp Schindler, Daniel Nigg and Rainer Blatt: Quantum information science: Experimental implementation with trapped ions; PART II: SEMINARS; 14 Jack G. E. Harris: An introduction to laser cooling optomechanical systems; 15 Christopher Eichler, Deniz Bozyigit, Christian Lang, Lars Steffen, Johannes Fink, and Andreas Wallraff: Tomography schemes for characterizing itinerant microwave photon fields; 16 Irfan Siddiqi: Using a friction-less pendulum for quantum measurement; 17 Alexander N. Korotkov: Quantum Bayesian approach to circuit QED measurement; 18 Yasunobu Nakamura: Superconducting quantum circuits: Artificial atoms coupled to 1D modes; 19 Olivier Buisson: A superconducting artificial atom with two internal degrees of freedom
About the author
Michel H. Devoret:
Department of Applied Physics, Yale University, New Haven, CT, USA
Collège de France, 11 Place Marcelin Berthelot, Paris, France
; Benjamin Huard:
Laboratoire Pierre Aigrain, CNRS, Ecole Normale Supérieure, Paris, France
; Robert Schoelkopf:
Department of Applied Physics, Yale University, New Haven, CT, USA
; Leticia F. Cugliandolo:
Laboratoire de Physique Theorique et Hautes Energies
Universite Pierre et Marie Curie - Paris 6, Paris, France
Summary
This book provides the basic knowledge needed to understand and investigate the physics of quantum machines, including quantum superconducting circuits, quantum dots, quantum nanomechanical resonators, trapped ions, single Rydberg atoms in superconducting cavities, and lattices of ultracold atoms.
