The deterministic generation of photons by cavity quantum electrodynamics

Walther, H.

doi:10.1002/prop.200610319

Cited by 8 publications

(12 citation statements)

References 141 publications

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“…Eqs. (16) and (22) as well as the realities of A l n ( ) and B l n ( ), C l n ( ) also turns out to be real. The exact solutions to these equations under the "initial" conditions in Eqs.…”

Section: Flow Equation Of the Jaynes-cummings Modelmentioning

confidence: 86%

Stationary photon–atom entanglement and flow equation

Itto¹,

Abe²

2008

Physica A: Statistical Mechanics and its Applications

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Stationary photon-atom entanglement is discussed by applying the method of flow equation to the Jaynes-Cummings model. A nonlocal continuous unitary transformation is explicitly constructed and the associated positive operator-valued measures for the photons and atom are obtained. Then, flow of the entanglement entropy is analyzed. A comment is also made on implementing the unitary operation in the method of flow equation. This method may offer a new strategy for quantum-state engineering.

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“…Eqs. (16) and (22) as well as the realities of A l n ( ) and B l n ( ), C l n ( ) also turns out to be real. The exact solutions to these equations under the "initial" conditions in Eqs.…”

Section: Flow Equation Of the Jaynes-cummings Modelmentioning

confidence: 86%

Stationary photon–atom entanglement and flow equation

Itto¹,

Abe²

2008

Physica A: Statistical Mechanics and its Applications

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“…The development of ultrashort laser pulses [12] together with the progress in ion trap technology [13] and cavity quantum electrodynamics [14] has opened a new avenue in the observation of the time evolution of wave packets. Indeed, the motion of a Rydberg electron [15], the center-of-mass motion of an ion stored in a Paul trap [16] or an atom in a standing wave [17] together with the periodic exchange of excitation between an atom and the photon field in a high-Q cavity [18] represent only a few examples of wave packets which are now almost routinely realized experimentally in many laboratories around the world.…”

Section: A Inverse Spectral Problemmentioning

confidence: 99%

Riemannζfunction from wave-packet dynamics

et al. 2010

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We show that the time evolution of a thermal phase state of an anharmonic oscillator with logarithmic energy spectrum is intimately connected to the generalized Riemann ζ function ζ (s,a). Indeed, the autocorrelation function at a time t is determined by ζ (σ + iτ,a), where σ is governed by the temperature of the thermal phase state and τ is proportional to t. We use the JWKB method to solve the inverse spectral problem for a general logarithmic energy spectrum; that is, we determine a family of potentials giving rise to such a spectrum. For large distances, all potentials display a universal behavior; they take the shape of a logarithm. However, their form close to the origin depends on the value of the Hurwitz parameter a in ζ (s,a). In particular, we establish a connection between the value of the potential energy at its minimum, the Hurwitz parameter and the Maslov index of JWKB. We compare and contrast exact and approximate eigenvalues of purely logarithmic potentials. Moreover, we use a numerical method to find a potential which leads to exact logarithmic eigenvalues. We discuss possible realizations of Riemann ζ wave-packet dynamics using cold atoms in appropriately tailored light fields.

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“…instead of the field outside the cavity, we again arrive at an equation of the form of Eq. (68), with the same functions φ (1) i (z, t) = φ i (z, t), but, in general, different associated operatorsb (1) out i (t) =b out i (t). Only in the limit of vanishing absorption they equal each other.…”

Section: Appendix C: Derivation Of Eq (31)mentioning

confidence: 99%

Cavity-assisted spontaneous emission as a single-photon source: Pulse shape and efficiency of one-photon Fock-state preparation

et al. 2008

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Within the framework of exact quantum electrodynamics in dispersing and absorbing media, we have studied the emission from an initially in the upper state prepared emitter in a high quality cavity in the case, when there are two cavity modes that resonantly interact with the emitter. In particular, when one of the modes is in resonance with the emitter transition and the other mode is tuned to the frequency equal to the Rabi splitting of the first mode, the effect of Rabi resonance is observed.

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The deterministic generation of photons by cavity quantum electrodynamics

Cited by 8 publications

References 141 publications

Stationary photon–atom entanglement and flow equation

Stationary photon–atom entanglement and flow equation

Riemannζfunction from wave-packet dynamics

Cavity-assisted spontaneous emission as a single-photon source: Pulse shape and efficiency of one-photon Fock-state preparation

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