Piezoelectric materials combined with nuclear spin alignment can source virtual QCD axions with up to 7 orders of magnitude enhanced scalar coupling, allowing resonant detection of the axion via spin precession in the 10^{-5} to 10^{-2} eV range.
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Axion-like particles in the trapped misalignment mechanism produce observable gravitational waves while generating intergalactic magnetic fields that exceed blazar lower bounds in the parameter space promising for gravitational wave detection.
Derives g_aγ ≲ 2×10^{-14} (10 kpc/R) GeV^{-1} constraints on ALP-photon coupling from absence of resonant photon growth in Galactic condensates using extragalactic background limits for 0.08 μeV to 8 eV masses.
citing papers explorer
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Detecting the QCD axion via the ferroaxionic force with piezoelectric materials
Piezoelectric materials combined with nuclear spin alignment can source virtual QCD axions with up to 7 orders of magnitude enhanced scalar coupling, allowing resonant detection of the axion via spin precession in the 10^{-5} to 10^{-2} eV range.
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Audible Axion Magnetogenesis: Linking Intergalactic Magnetic Fields and Gravitational Waves
Axion-like particles in the trapped misalignment mechanism produce observable gravitational waves while generating intergalactic magnetic fields that exceed blazar lower bounds in the parameter space promising for gravitational wave detection.
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Axion Condensate Dark Matter Constraints from Resonant Enhancement of Background Radiation
Derives g_aγ ≲ 2×10^{-14} (10 kpc/R) GeV^{-1} constraints on ALP-photon coupling from absence of resonant photon growth in Galactic condensates using extragalactic background limits for 0.08 μeV to 8 eV masses.