Non-Lorentzian laser line shapes and the reversed peak asymmetry in double optical resonance
- 1 April 1980
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review A
- Vol. 21 (4), 1289-1296
- https://doi.org/10.1103/physreva.21.1289
Abstract
The interaction of an atomic system with a laser having phase fluctuations is studied within the phase-diffusion model, with the finite correlation time of the time derivative of the phase taken into account. This finite correlation time introduces a line shape which is Lorentzian near the center and falls off faster than the Lorentzian at its wings. The authors apply this model to calculate the spectrum of double optical resonance for excitation by a laser having this non-Lorentzian line shape. It is observed that the reversed peak asymmetry reverts to normal far off resonance owing to the cutoff of the laser spectrum, in agreement with recent experiments. Numerical results are presented.Keywords
This publication has 22 references indexed in Scilit:
- ac Stark splitting in double optical resonance and resonance fluorescence by a nonmonochromatic chaotic fieldPhysical Review A, 1979
- Resonant multiphoton ionization by finite-bandwidth chaotic fieldsPhysical Review A, 1979
- Quantum statistical theory of optical-resonance phenomena in fluctuating laser fieldsPhysical Review A, 1978
- ac Stark splitting in doubly resonant three-photon ionization with nonmonochromatic fieldsPhysical Review A, 1978
- Asymmetric resonance fluorescence spectra in partially coherent fieldsPhysical Review A, 1978
- Resonance fluorescence in modulated laser fieldsJournal of Physics B: Atomic and Molecular Physics, 1977
- Fokker-Planck equation treatment of atomic relaxation and resonance fluorescence in phase-modulated laser lightJournal of Physics B: Atomic and Molecular Physics, 1977
- Resonance fluorescence with excitation of finite bandwidthPhysical Review A, 1977
- Two-level atom saturated by a fluctuating resonant laser beam. Calculation of the fluorescence spectrumJournal of Physics B: Atomic and Molecular Physics, 1977
- Atomic Relaxation in the Presence of Intense Partially Coherent Radiation FieldsPhysical Review Letters, 1976