CAVITY QUANTUM ELECTRODYNAMICS HAROCHE PDF

For instance, spontaneous emission rates can be altered, the energy levels may be shifted. In extreme situations, the spontaneous emission may even become a reversible, oscillatory process. This process is experimental and the keywords may be updated as the learning algorithm improves. This is a preview of subscription content, log in to check access.

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Here we adapt this general theory to a system represented by a single-mode cavity field coupled to a reservoir of harmonic oscillators. We first derive the master equation, the Fokker-Planck equation and the Heisenberg-Langevin equations of motion for the cavity field. We then discuss certain aspects of cavity quantum electrodynamics QED which studies the behavior of an atom interacting with the cavity field. In particular, we consider a two-level atom in a leaky cavity and show that, depending on the parameters of the cavity, the atom-cavity system can exhibit damped Rabi oscillations, or the optical cavity can modify the rate of atomic spontaneous emission.

Finally, we demonstrate that by employing the STIRAP techniques with a three-level atom confined in a leaky cavity, one can realize a deterministic source of single-photons. Other aspects of cavity QED will be discussed in Chap. This process is experimental and the keywords may be updated as the learning algorithm improves. This is a preview of subscription content, log in to check access. Preview Unable to display preview. Download preview PDF.

Purcell, Spontaneous emission probabilities at radio frequencies, Phys. Kleppner, Inhibited spontaneous emission, Phys. Goy, J. Raimond, M. Gross and S. Haroche, Observation of cavity-enhanced single-atom spontaneous emission, Phys. Haroche and J. Kuhn, M. Hennrich and G. Rempe, Deterministic single-photon source for distributed quantum networking, Phys. McKeever, A. Boca, A. Boozer, R. Miller, J. Buck, A. Kuzmich and H. Keller, B. Lange, K. Hayasaka, W. Lange and H.

Walther, Continuous generation of single photons with controlled waveform in an ion-trap cavity system, Nature , Khitrova, H. Gibbs, M. Kira, S. Koch and A. Scherer, Vacuum Rabi splitting in semiconductors, Nature Physics 2, 81

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Cavity Quantum Electrodynamics

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From cavity to circuit quantum electrodynamics

Here we adapt this general theory to a system represented by a single-mode cavity field coupled to a reservoir of harmonic oscillators. We first derive the master equation, the Fokker-Planck equation and the Heisenberg-Langevin equations of motion for the cavity field. We then discuss certain aspects of cavity quantum electrodynamics QED which studies the behavior of an atom interacting with the cavity field. In particular, we consider a two-level atom in a leaky cavity and show that, depending on the parameters of the cavity, the atom-cavity system can exhibit damped Rabi oscillations, or the optical cavity can modify the rate of atomic spontaneous emission. Finally, we demonstrate that by employing the STIRAP techniques with a three-level atom confined in a leaky cavity, one can realize a deterministic source of single-photons.

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Basics of Cavity Quantum Electrodynamics

The full article with images, which appeared in the April issue, is available for purchase here. Fleeting, spontaneous transitions are ubiquitous in the quantum world. Once they are under way, they seem as uncontrollable and as irreversible as the explosion of fireworks. Excited atoms, for example, discharge their excess energy in the form of photons that escape to infinity at the speed of light.

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Cavity quantum electrodynamics

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