Theoretical modeling of resonant laser excitation of atoms in a magnetic field

Andrew James Murray; William MacGillivray; Martyn Hussey

doi:10.1103/PhysRevA.77.013409

Theoretical modeling of resonant laser excitation of atoms in a magnetic field

Andrew James Murray, William MacGillivray, Martyn Hussey

Research output: Contribution to journal › Article › peer-review

Abstract

The interaction of near-resonant laser radiation with atoms immersed in a magnetic B field is calculated using a quantum electrodynamic model. In this model, the magnetic field is assumed to produce a small perturbation such that the degeneracy of the magnetic substates is lifted while maintaining the usual quantum numbers that define the states (the Zeeman effect). The laser radiation is considered to have a narrow bandwidth and to be temporally and spatially coherent. The model produces three general coupled differential equations that describe the state populations and their relative coherences and the optical coherences between levels coupled by the laser radiation. The model can therefore be directly applied to different experiments ranging from atom trapping and cooling experiments through to collision experiments carried out in magnetic and laser fields. © 2008 The American Physical Society.

Original language	English
Article number	013409
Journal	Physical Review A
Volume	77
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevA.77.013409
Publication status	Published - 23 Jan 2008

Keywords

SUPERELASTIC-SCATTERING
STEPWISE ELECTRON
STATE
CALCIUM
SODIUM
IMPACT

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10.1103/PhysRevA.77.013409

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Cite this

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title = "Theoretical modeling of resonant laser excitation of atoms in a magnetic field",

abstract = "The interaction of near-resonant laser radiation with atoms immersed in a magnetic B field is calculated using a quantum electrodynamic model. In this model, the magnetic field is assumed to produce a small perturbation such that the degeneracy of the magnetic substates is lifted while maintaining the usual quantum numbers that define the states (the Zeeman effect). The laser radiation is considered to have a narrow bandwidth and to be temporally and spatially coherent. The model produces three general coupled differential equations that describe the state populations and their relative coherences and the optical coherences between levels coupled by the laser radiation. The model can therefore be directly applied to different experiments ranging from atom trapping and cooling experiments through to collision experiments carried out in magnetic and laser fields. {\textcopyright} 2008 The American Physical Society.",

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N2 - The interaction of near-resonant laser radiation with atoms immersed in a magnetic B field is calculated using a quantum electrodynamic model. In this model, the magnetic field is assumed to produce a small perturbation such that the degeneracy of the magnetic substates is lifted while maintaining the usual quantum numbers that define the states (the Zeeman effect). The laser radiation is considered to have a narrow bandwidth and to be temporally and spatially coherent. The model produces three general coupled differential equations that describe the state populations and their relative coherences and the optical coherences between levels coupled by the laser radiation. The model can therefore be directly applied to different experiments ranging from atom trapping and cooling experiments through to collision experiments carried out in magnetic and laser fields. © 2008 The American Physical Society.

AB - The interaction of near-resonant laser radiation with atoms immersed in a magnetic B field is calculated using a quantum electrodynamic model. In this model, the magnetic field is assumed to produce a small perturbation such that the degeneracy of the magnetic substates is lifted while maintaining the usual quantum numbers that define the states (the Zeeman effect). The laser radiation is considered to have a narrow bandwidth and to be temporally and spatially coherent. The model produces three general coupled differential equations that describe the state populations and their relative coherences and the optical coherences between levels coupled by the laser radiation. The model can therefore be directly applied to different experiments ranging from atom trapping and cooling experiments through to collision experiments carried out in magnetic and laser fields. © 2008 The American Physical Society.

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KW - STEPWISE ELECTRON

KW - STATE

KW - CALCIUM

KW - SODIUM

KW - IMPACT

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Theoretical modeling of resonant laser excitation of atoms in a magnetic field

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Keywords

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