01023nam1-2200373---450-99000323193020331620090429172641.0000323193USA01000323193(ALEPH)000323193USA0100032319320090429d1979----km-y0itay50------baengUS||||||||001yy<<Vol. 2: >> 1951-1964André Weilcorrected second printingNew YorkSpringer1979XII, 561 p.24 cm200120010010003231912001Oeuvres scientifiques. Collected papersMatematicaBNCF510WEIL,André348138ITsalbcISBD990003231930203316510 WEI/210319/CBS51000218491BKSCIRSIAV79020090429USA011726RSIAV79020090429USA0117261951-19641013251UNISA05487nam 22005173 450 991098566770332120240407090434.097807503442100750344210(MiAaPQ)EBC31253120(Au-PeEL)EBL31253120(CKB)31356167100041(Exl-AI)31253120(OCoLC)1429736878(EXLCZ)993135616710004120240407d2022 uy 0engurcnu||||||||txtrdacontentcrdamediacrrdacarrierThe Jaynes-Cummings Model and Its Descendants Modern Research Directions1st ed.Bristol :Institute of Physics Publishing,2022.©2021.1 online resource (426 pages)IOP Series in Quantum Technology Series9780750334488 0750334487 Intro -- Foreword -- Acknowledgement -- Authors biographies -- Jonas Larson -- Themistoklis Mavrogordatos -- Introduction -- References -- Chapter 1 Theoretical aspects -- 1.1 The Jaynes-Cummings model -- 1.2 Jaynes-Cummings dynamics -- 1.2.1 General solution and remarks -- 1.2.2 Collapse-revival -- 1.2.3 Semiclassical regime and the classical limit -- 1.2.4 Entanglement -- 1.2.5 Squeezing -- 1.3 Driven and open Jaynes-Cummings physics -- 1.3.1 Field or atom driving -- 1.3.2 Applying the open systems formalism -- 1.3.3 Quantum fluctuations and criticality: photon blockade and its breakdown -- 1.4 Beyond the rotating wave approximation: the quantum Rabi model -- 1.4.1 Effect of counter rotating terms, the ultrastrong coupling regime -- 1.4.2 Analytical approximations -- 1.4.3 Integrability of the quantum Rabi model -- 1.5 Extended Jaynes-Cummings models -- 1.5.1 Kerr medium and intensity dependent or multi-photon couplings -- 1.5.2 Multimode and multi-level atoms -- 1.5.3 Time-dependent and adiabatic Jaynes-Cummings models -- 1.5.4 Quantized atomic motion -- 1.5.5 The Dicke and Tavis-Cummings models -- 1.5.6 'Poor man's models' -- 1.6 Extended Jaynes-Cummings models turned into single particle lattice problems -- 1.6.1 Fock-state lattices of single-mode models -- 1.6.2 Fock-state lattices of multimode models -- 1.6.3 Fractal spectra -- 1.6.4 State transfer and edge states -- 1.7 Review of the approximations underlying the JC model -- 1.7.1 Electric dipole approximation -- 1.7.2 Single-mode approximation -- 1.7.3 Two-level approximation -- 1.7.4 Rotating-wave approximation -- 1.7.5 Neglecting the self-energy diamagnetic term -- 1.7.6 Neglecting the kinetic energy term -- 1.7.7 Neglecting losses -- References -- Chapter 2 Cavity QED -- 2.1 Early results and predictions -- 2.1.1 Optical bistability -- 2.1.2 The micromaser.2.2 Cavity-induced atomic forces -- 2.3 State preparation -- 2.3.1 Fock states -- 2.3.2 Schrödinger cat states -- 2.3.3 Entangled states -- 2.4 State tomography -- 2.5 Quantum information processing -- 2.6 Quantum fluctuations and coherence in the weak-excitation limit -- References -- Chapter 3 Circuit QED -- 3.1 From the Cooper pair box to the transmon qubit: the generalized Jaynes-Cummings model -- 3.2 Engineering the coupling strength -- 3.3 Mitigating dispersion and decoherence -- 3.4 The (generalized) JC nonlinearity and spectrum revisited in the light of circuit QED -- 3.5 Control and transfer of quantum information in circuit QED -- References -- Chapter 4 Trapped ions -- 4.1 Model Hamiltonians -- 4.2 State preparation and tomography -- 4.3 Quantum information processing -- 4.4 Further aspects and perspectives -- References -- Chapter 5 Waveguide QED -- 5.1 Atomic emission in the vicinity of an interface -- 5.2 Circuit QED revisited -- 5.3 Light-matter interaction in a 1D waveguide: a continuum for correlated photon states -- 5.4 Interaction with matter in nanowire plasmons -- References -- Chapter 6 Alternative physical systems -- 6.1 Nitrogen vacancy centers -- 6.2 Strong coupling in photonic crystals -- 6.3 Hybrid systems: from nanomechanics to atomic ensembles -- References -- Chapter 7 Extensions to many-body configurations and additional degrees of freedom -- 7.1 Jaynes-Cummings-Hubbard models -- 7.2 Many-body cavity QED -- 7.2.1 Mean-field explorations -- 7.2.2 Critical phenomena I-bosons -- 7.2.3 Critical phenomena II-fermions -- 7.3 Polaritonic chemistry -- 7.3.1 Born-Oppenheimer theory -- 7.3.2 Molecular JC Hamiltonian -- References -- Conclusions 8 A projection for the coming decades -- References -- Index.This comprehensive review conveys the fundamental generality of the Jaynes-Cummings Model's (JCM) formalism, looking at a wide range of applications in specific physical systems and across disciplines including atomic physics, quantum optics, solid-state physics and quantum information sciences. It is an ideal reference for researchers in quantum physics and quantum optics.IOP Series in Quantum Technology SeriesQuantum opticsGenerated by AIQuantum electrodynamicsGenerated by AIQuantum opticsQuantum electrodynamicsLarson Jonas890813Mavrogordatos Themistoklis1791920MiAaPQMiAaPQMiAaPQBOOK9910985667703321The Jaynes-Cummings Model and Its Descendants4329715UNINA