Atomic and molecular transitions induced by axions via oscillating nuclear moments

The interaction of the standard model's particles with the axionic dark matter field may generate oscillating nuclear electric dipole moments (EDMs), oscillating nuclear Schiff moments, and oscillating nuclear magnetic quadrupole moments (MQMs) with a frequency corresponding to the axion's...

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Bibliographic Details
Published in:Physical review. D 2020-04, Vol.101 (7), p.1, Article 073004
Main Authors: Flambaum, V. V., Tan, H. B. Tran, Budker, D., Wickenbrock, A.
Format: Article
Language:English
Subjects:
Background noise
Dark matter
Deformation
Dipole moments
Electric dipoles
Fluorescence
Photoionization
Quadrupoles
Standard model (particle physics)
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Summary:The interaction of the standard model's particles with the axionic dark matter field may generate oscillating nuclear electric dipole moments (EDMs), oscillating nuclear Schiff moments, and oscillating nuclear magnetic quadrupole moments (MQMs) with a frequency corresponding to the axion's Compton frequency. Within an atom or a molecule an oscillating EDM, Schiff moment, or MQM can drive transitions between atomic or molecular states. The excitation events can be detected, for example, via subsequent fluorescence or photoionization. Here we calculate the rates of such transitions. If the nucleus has octupole deformation or quadrupole deformation, then the transition rate due to the Schiff moment and MQM can be up to 10−16 transition per molecule per year. In addition, an MQM-induced transition may be of M2-type, which is useful for the elimination of background noise since M2-type transitions are suppressed for photons.
ISSN:2470-0010
2470-0029
DOI:10.1103/PhysRevD.101.073004