Optical mixing of frequencies of a strong bichromatic field interacting with a three-level atom

1981 ◽  
Vol 59 (12) ◽  
pp. 1917-1929 ◽  
Author(s):  
Constantine Mavroyannis
Keyword(s):  
Spectral Function ◽  
Excitation Spectrum ◽  
Graphical Representation ◽  
Single Band ◽  
Laser Fields ◽  
Optical Amplification ◽  
Lorentzian Line ◽  
Level Atom ◽  
Bichromatic Field ◽  
Optical Mixing

We have studied the excitation spectrum arising from the optical mixing of the frequencies of a strong bichromatic field interacting with a three-level atom, where the two initially populated modes ωa and ωb are equal to the two atomic transition frequencies, respectively. In the limit of high photon densities, the excitation spectrum near the frequency ω = ωa – 2ωb has been calculated as a function of the parameter η = Ωa2/Ωb2, where Ωa and Ωb are the Rabi frequencies of the two laser fields, respectively. For [Formula: see text] and for weak fields for which [Formula: see text], the spectral function describes a Lorentzian line peaked at the frequency ω = ωa – 2ωb and has a width of the order of γ0, where γ0/2 is the natural width for a two-level atom. When Ωb2 > γ02 and [Formula: see text], the band at ω = ωa – 2ωb splits into two bands described by two Lorentzian lines peaked at ω = ωa – 2ωb ± Ωb/√2 and have spectral widths of the order of 3γ0/4. The ratio of the height of the band ω = ωa – 2ωb to the height ω = ωa – 2ωb ± Ωb/2 is 3:2. The probability amplitudes for both bands take large negative values indicating that optical amplification of the signal field may be expected to occur at these frequencies. When Ωa = Ωb = Ω, η = 1, and for Ω2 < γ02, the spectral function describes a single band at ω = ωa – 2ωb while for Ω2 > γ02, the single band splits into five pairs of bands which are separated from the frequency ω = ωa – 2ωb by frequency shifts which are equal to: ± Ω/√2, [Formula: see text], ± Ω, ± Ω√2, and ± Ω√3, respectively, and have spectral widths of the order of 3γ0/4. For [Formula: see text] and for laser fields for which Ωa2 > γ02 and Ωb2 > γ02, the spectral function consists of three pairs of bands. The probability amplitudes for these bands vary linearly with η and may take large values for [Formula: see text]. A complete discussion of the excitation spectrum as well as a graphical representation of the derived results has been given.

Resonance fluorescence spectra from a three-level atom interacting with a strong bichromatic field

1980 ◽  
Vol 58 (11) ◽  
pp. 1570-1579 ◽  
Author(s):  
M. P. Sharma ◽  
A. Balbin Villaverde ◽  
Constantine Mavroyannis
Keyword(s):  
Closed Form ◽  
Spectral Function ◽  
Excitation Spectrum ◽  
Electromagnetic Fields ◽  
Fluorescence Spectra ◽  
Central Peak ◽  
Relative Strength ◽  
Resonance Fluorescence ◽  
Level Atom ◽  
Bichromatic Field

We have studied the fluorescence spectra arising from the interaction of a three-level atom with two strong electromagnetic fields whose initially populated modes are equal to the two atomic transition frequencies, respectively. The Green's function formalism has been used to calculate the excitation spectrum of the system. An expression for the spectral function describing the excitation spectrum of the system has been derived in a closed form in the limit of high photon densities. Numerical computation of the expression for the spectral function indicates that at each transition frequency there may exist either one pair or two pairs or three pairs of sidebands, in addition to the central peak, depending upon the relative strength of the Rabi frequencies involved.

Optical mixing of frequencies of a strong bichromatic field interacting with a three-level atom. II. Numerical results

1982 ◽  
Vol 60 (2) ◽  
pp. 245-251 ◽  
Author(s):  
Constantine Mavroyannis ◽  
K. J. Woloschuk ◽  
D. A. Hutchinson ◽  
Christine Downie
Keyword(s):  
Ground State ◽  
Laser Field ◽  
Excitation Spectra ◽  
Laser Fields ◽  
Level Atom ◽  
Reduced Frequency ◽  
Spontaneous Emission Probability ◽  
Bichromatic Field ◽  
Optical Mixing ◽  
Selection Of

We have numerically calculated the excitation spectra arising from the 3rd order mixing of the frequencies ωa and ωb of two laser fields interacting with a three-level atom, where each laser field resonantly couples the ground state with each excited state of the atom, respectively. In the limit of high photon densities, the excitation spectra near the reduced frequency X = (ω−ωa + 2ωb)/γ0 ≈ 0 are considered as a function of the reduced Rabi frequencies ηa and ηb of the two laser fields, respectively and γ0 is the spontaneous emission probability. For ηa < ηb the spectra consist of a doublet peaked at [Formula: see text] and its intensity is constant. When ηa = ηb, the spectra are composed of five pairs of bands peaked at [Formula: see text], and [Formula: see text]. When ηa < ηb the computed spectra consist of five pairs of bands, where the intensities of the peaks at [Formula: see text] and [Formula: see text] are positive indicating absorption, those at [Formula: see text] are negative implying amplification, and the two pairs of peaks at [Formula: see text] have positive and negative components describing the mixed process of absorption–amplification. The intensities of these bands are found to vary as (ηa/ηb)2 for (ηa/ηb) > 1 and, therefore, the intensities of the bands are immensely enhanced as the value of the ratio (ηa/ηb) increases. The computed spectra for a wide selection of Rabi frequencies are graphically presented and compared with those derived by analytical methods.

Interference effects in the resonance fluorescence of a three-level atom at high proton densities

1980 ◽  
Vol 58 (7) ◽  
pp. 957-963 ◽  
Author(s):  
Constantine Mavroyannis
Keyword(s):  
Excitation Spectrum ◽  
Beat Frequency ◽  
Low Frequency ◽  
Delta Function ◽  
Resonance Fluorescence ◽  
Interference Effects ◽  
Lorentzian Line ◽  
Level Atom ◽  
Upper Level ◽  
The Stability

A theory on interference effects at high photon densities has been developed for two types of a single three-level atom for which transitions occur: (i) from two different upper levels to a common lower one and (ii) from a common upper level to two different lower levels. The excitation spectrum for the interference effects for the two types of atoms results from the symmetric and antisymmetric interference between the two electronic transitions of the system, respectively. The spectral function for the symmetric modes consists of three Lorentzian lines peaked at the frequencies ω = Δ and ω = Δ ± Ω and having spectral widths of the order of γ0 and 3γ0/4, respectively, where Δ is the beat frequency, Ω is the Rabi frequency, and γ0/2 is equal to the natural linewidth for a photon spontaneously emitted from an isolated atom. The antisy mmetric spectrum consists of the peak of ω = Δ, which has a delta-function distribution indicating the stability of the mode in question, and two Lorentzian lines peaked at ω = Δ ± Ω with radiative widths of the order of γ0/2. The excitation spectrum of each type of atom contains also a Lorentzian line describing the very low frequency mode of the system, respectively.

Non-linear optical mixing of frequencies of a strong bichromatic field interacting with a two-level atom at high photon densities

1983 ◽  
Vol 49 (3) ◽  
pp. 631-643 ◽  
Author(s):  
Constantine Mavroyannis ◽  
K.J. Woloschuk
Keyword(s):  
Level Atom ◽  
Bichromatic Field ◽  
Non Linear ◽  
Optical Mixing ◽  
Linear Optical

Kinetic theory of (2 + 4)-level atom in σ + – σ − laser fields

2009 ◽  
Vol 18 (8) ◽  
pp. 3395-3403
Author(s):  
Yu Chuang ◽  
Yu De-Shui ◽  
Chen Jing-Biao
Keyword(s):  
Kinetic Theory ◽  
Laser Fields ◽  
Level Atom

Effect of quantum interference on a three-level atom driven by two laser fields

2001 ◽  
Vol 48 (6) ◽  
pp. 1059-1084 ◽  
Author(s):  
Uzma Akram ◽  
Z. Ficek ◽  
S. Swain
Keyword(s):  
Quantum Interference ◽  
Laser Fields ◽  
Level Atom

Phase Effects in Bichromatic Field Interactions with a Two-Level Atom

1985 ◽  
Vol 55 (10) ◽  
pp. 1070-1073 ◽  
Author(s):  
Roger E. Silverans ◽  
Gustaaf Borghs ◽  
Peter De Bisschop ◽  
Marleen Van Hove
Keyword(s):  
Level Atom ◽  
Bichromatic Field
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