Continuum fields in quantum optics
- 1 October 1990
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review A
- Vol. 42 (7) , 4102-4114
- https://doi.org/10.1103/physreva.42.4102
Abstract
We formulate the quantum theory of optical wave propagation without recourse to cavity quantization. This approach avoids the introduction of a box-related mode spacing and enables us to use a continuum frequency space description. We introduce a complete orthonormal set of operators that can describe states of finite energy. The set is countable and the operators have all the usual properties of the single-mode frequency operators. With use of these operators a generalization of the single-mode normal-ordering theorem is proved. We discuss the inclusion of material dispersion and pulse propagation in an optical fiber. Finally, we consider the process of photodetection in free space, concluding with a discussion of homodyne detection with both local oscillator and signal fields pulsed.Keywords
This publication has 16 references indexed in Scilit:
- Squeezed-light generation with an incoherent pumpPhysical Review Letters, 1990
- Quantization and phase-space methods for slowly varying optical fields in a dispersive nonlinear mediumPhysical Review A, 1988
- Quantum wideband traveling-wave analysis of a degenerate parametric amplifierJournal of the Optical Society of America B, 1987
- Squeezed LightJournal of Modern Optics, 1987
- Quantum Theory of Optical Homodyne and Heterodyne DetectionJournal of Modern Optics, 1987
- Quantum theory of light propagation: Linear mediumPhysical Review A, 1987
- Spatial dependence of weakly localized single-photon wave packetsPhysical Review A, 1987
- Optical communication with two-photon coherent states--Part III: Quantum measurements realizable with photoemissive detectorsIEEE Transactions on Information Theory, 1980
- Quantum Theory of an Optical Maser. III. Theory of Photoelectron Counting StatisticsPhysical Review B, 1969
- Quantum Theory of Field AttenuationPhysical Review B, 1968