The optical dump at the LUXE experiment has the potential to create a large flux of O (GeV) photons that can be used to look for new physics when directed at a solid material dump. The LUXE-NPOD extension of LUXE, which focuses the hard photons onto a slab of tungsten, offers two interaction points (laser-electron and photon-tungsten), making it well-suited to test theories containing two or more new particles. We examine the dark axion portal, a scenario involving both dark photons (DPs) and axion-like particles (ALPs) and their mutual interactions, and its implications on the phenomenology at LUXE-NPOD. To simulate the spectra of particle populations generated at the electron-laser interaction point, we solve a set of extended 1D cascade equations. We recover a photon spectrum consistent with previous analyses and present previously unconsidered DP and ALP spectra. We derive the overall sensitivity of LUXE-NPOD to various parameters of the new particles, and show that it is capable of probing previously uncharted regions in the dark axion parameter space. For ALPs in the 10-500 MeV mass range and DPs either heavier (GeV) or significantly lighter O (10^-18-10^-13) eV, we obtain novel constraints on DP kinetic mixing parameters smaller than 10^-2 and on O (10^-4-10^-3) GeV^-1 ALP-photon couplings. We find that restrictions on O (10^-3) kinetic mixing can be extracted for arbitrarily small DP masses. Our discussion aims to be systematic and demonstrates a practical method of analyzing constraints on multi-dimensional parameter spaces.
Ness et al. (Fri,) studied this question.
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