Quantum theory of the resonance interaction of an intense monochromatic electromagnetic wave with arbitrary polarization composition

Abstract

A theory describing the absorption and emission spectra of an atomic transition in the field of an intense monochromatic wave with arbitrary polarization composition is developed. The theory includes a quantum description of forward-directed four-wave interaction processes. Expressions are obtained for describing the absorption and emission spectra in transitions adjacent to the working transition. The description developed includes the perturbation of the atomic subsystem by a constant magnetic field. The spectral characteristics, polarization composition, and angular distribution of the resonance fluorescence are investigated. The nonlinear Faraday effect and the properties of resonance fluorescence are investigated for the transition J=1→J=0.