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A new probe of Axion-Like Particles: CMB polarization distortions due to cluster magnetic fields

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arxiv 1908.07534 v2 pith:T6SZSS2T submitted 2019-08-20 astro-ph.CO hep-phhep-th

A new probe of Axion-Like Particles: CMB polarization distortions due to cluster magnetic fields

classification astro-ph.CO hep-phhep-th
keywords clustermagneticsignalgalaxyalpsaroundcmb-s4distortion
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We propose using the upcoming Cosmic Microwave Background (CMB) ground based experiments to detect the signal of ALPs (Axion like particles) interacting with magnetic fields in galaxy clusters. The conversion between CMB photons and ALPs in the presence of the cluster magnetic field can cause a polarized spectral distortion in the CMB around a galaxy cluster. The strength of the signal depends upon the redshift of the galaxy cluster and will exhibit a distinctive spatial profile around it depending upon the structure of electron density and magnetic field. This distortion produces a different shape from the other known spectral distortions like $y$-type and $\mu$-type and hence are separable from the multi-frequency CMB observation. The spectrum is close to kinematic Sunyaev-Zeldovich (kSZ) signal but can be separated from it using the polarization information. For the future ground-based CMB experiments such as Simons Observatory and CMB-S4, we estimate the measurability of this signal in the presence of foreground contamination, instrument noise and CMB anisotropies. This new avenue can probe the photon-ALP coupling over the ALP mass range from $10^{-13}$ eV to $10^{-12}$ eV with two orders of magnitude better accuracy from CMB-S4 than the current existing bounds.

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