1989
DOI: 10.1103/physrevd.39.2089
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Design for a practical laboratory detector for solar axions

Abstract: We present a practical design for a detector sensitive to axions and other light particles with a two-photon interaction vertex. Such particles would be produced in the solar interior by Primakoff conversion of blackbody photons and could be detected by their reconversion into x rays (average energy about 4 keV) in a strong laboratory magnetic field. An existing large superconducting magnet would be suitable for this purpose. The transition rate is enhanced by filling the conversion region with a buffer gas (H… Show more

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Cited by 245 publications
(297 citation statements)
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“…Solar axions have an average energy ω a ≃ 4 keV [10], which upon conversion in the magnetosphere will turn into x-ray photons of the same energy. The absorption length λ x for 4-keV x-rays in the Earth's atmosphere is about 10 cm at sea-level [11].…”
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confidence: 99%
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“…Solar axions have an average energy ω a ≃ 4 keV [10], which upon conversion in the magnetosphere will turn into x-ray photons of the same energy. The absorption length λ x for 4-keV x-rays in the Earth's atmosphere is about 10 cm at sea-level [11].…”
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confidence: 99%
“…For this plot we integrated the conversion probability as given in Eq. (4) folded with solar axion spectrum [5,10] over axion energies from 1 − 10 keV.…”
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confidence: 99%
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“…This restricts the sensitivity of a helioscope to a specific range of axion masses, e.g., for a 10 m long magnet and axion energy of ∼10 keV the coherence condition sets the limit of m a ∼ < 0.03 eV on the axion mass, up to which such an experiment is sensitive. However, coherence can be maintained for higher axion masses if the conversion volume is filled with a buffer gas such as helium [13]. In this case, photons acquire an effective mass m γ whose value is determined by the gas pressure, and the axion-photon momentum difference becomes q = m 2 γ − m 2 a /2E a .…”
Section: The Detection Of Solar Axions In the Cast Experimentsmentioning
confidence: 99%
“…Such axions would have a continuous energy spectrum peaked near the mean energy of 4.2 keV and dying off above ∼10 keV. Most of the experiments that have been designed to search for these axions are based on the coherent axion-to-photon reconversion in a laboratory transverse magnetic field (the axion helioscope method [11][12][13][14][15][16][17][18][19][20][21]), or in the intense Coulomb field of nuclei in a crystal lattice of the detector (the Bragg scattering technique [22][23][24][25][26]). …”
Section: Introductionmentioning
confidence: 99%