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101 0 $aeng
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181   $ctxt$2rdacontent
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200 14$aThe Jaynes-Cummings Model and Its Descendants $eModern Research Directions
205   $a1st ed.
210  1$aBristol :$cInstitute of Physics Publishing,$d2022.
210  4$d©2021.
215   $a1 online resource (426 pages)
225 1 $aIOP Series in Quantum Technology Series
311 08$a9780750334488 
311 08$a0750334487 
327   $aIntro -- 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.
327   $a2.2 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.
330   $aThis comprehensive review conveys the fundamental generality of the Jaynes-Cummings Model's (JCM) formalism, looking at a wide range of applications in specific physical systems and across disciplines including atomic physics, quantum optics, solid-state physics and quantum information sciences. It is an ideal reference for researchers in quantum physics and quantum optics.
410  0$aIOP Series in Quantum Technology Series
606   $aQuantum optics$7Generated by AI
606   $aQuantum electrodynamics$7Generated by AI
615  0$aQuantum optics
615  0$aQuantum electrodynamics
700   $aLarson$b Jonas$0890813
701   $aMavrogordatos$b Themistoklis$01791920
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910985667703321
996   $aThe Jaynes-Cummings Model and Its Descendants$94329715
997   $aUNINA