Search for solar Kaluza-Klein axions in theories of low-scale quantum gravity
Abstract
We explore the physics potential of a terrestrial detector for observing axionic Kaluza-Klein excitations coming from the Sun within the context of higher-dimensional theories of low-scale quantum gravity. In these theories, the heavier Kaluza-Klein axions are relatively short-lived and may be detected by a coincidental triggering of their two-photon decay mode. Because of the expected high multiplicity of the solar axionic excitations, we find experimental sensitivity to a fundamental Peccei-Quinn axion mass up to 10-2 eV (corresponding to an effective axion-photon coupling gaγ γ ≈ 2.× 10-12 GeV-1) in theories with 2 extra dimensions and a fundamental quantum-gravity scale M F of order 100 TeV, and up to 3.× 10-3 eV (corresponding to gaγ γ ≈ 6.× 10-13 GeV-1) in theories with 3 extra dimensions and M F=1 TeV. For comparison, based on recent data obtained from lowest level underground experiments, we derive the experimental limits: ga γ γ < 2.5× 10-11 GeV-1 and ga γ γ < 1.2× 10-11 GeV-1 in the aforementioned theories with 2 and 3 large compact dimensions, respectively.
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