Elsevier B.V. : Neutron stars as photon double-lenses: Constraining resonant conversion into ALPs

Bondarenko, Kyrylo; Sokolenko, Anastasia; Boyarsky, Alexey; Pradler, Josef

doi:10.1016/j.physletb.2023.138238

Article
Report number	arXiv:2203.08663 ; UWThPh 2023-22 ; FERMILAB-PUB-22-170-V
Title	Neutron stars as photon double-lenses: Constraining resonant conversion into ALPs
Author(s)	Bondarenko, Kyrylo (IFPU, Trieste ; SISSA, Trieste ; INFN, Trieste) ; Boyarsky, Alexey (Leiden U.) ; Pradler, Josef (Vienna, OAW ; Vienna U. ; CERN) ; Sokolenko, Anastasia (Fermilab ; Chicago U., KICP)
Publication	2023-10-11
Imprint	2022-03-16
Number of pages	7
In:	Phys. Lett. B 846 (2023) 138238
DOI	10.1016/j.physletb.2023.138238 (publication)
Subject category	astro-ph.HE ; Astrophysics and Astronomy ; hep-ph ; Particle Physics - Phenomenology
Abstract	Axion-photon conversion is a prime mechanism to detect axion-like particles that share a coupling to the photon. We point out that in the vicinity of neutron stars with strong magnetic fields, magnetars, the effective photon mass receives comparable but opposite contributions from free electrons and the radiation field. This leads to an energy-dependent resonance condition for conversion that can be met for arbitrary light axions and leveraged when using systems with detected radio component. Using the magnetar SGR J1745-2900 as an exemplary source, we demonstrate that sensitivity to $\|g_{a\gamma}\| \sim 10^{-12}\,\rm{GeV^{-1}}$ or better can be gained for $m_a \lesssim 10^{-6}\,\rm eV$, with the potential to improve current constraints on the axion-photon coupling by more than one order of magnitude over a broad mass range. With growing insights into the physical conditions of magnetospheres of magnetars, the method hosts the potential to become a serious competitor to future experiments such as ALPS-II and IAXO in the search for axion-like particles.
Copyright/License	publication: © 2023-2024 US government (License: CC BY 4.0), sponsored by SCOAP³ preprint: (License: CC BY 4.0)

$Real branch of the effective photon mass as a function of photon frequency $\nu$ and electron densities as labeled. The solid (dashed) red lines represent a neutron star environment with $B=10^{14}$~G ($10^{15}$~G). For comparison, the gray horizontal line shows a typical galaxy cluster central density~\cite{Sarazin:1986zz}. The 1$\sigma$-3$\sigma$ shaded bands are inferred from the free electron distribution of the large scale structure at $z=0$~\cite{Garcia:2020qrp}.$ $High-frequency radio spectrum of SGR J1745-2900 during two observational campaigns over several days in 2014~\cite{Torne:2015rha} and 2015~\cite{Torne:2016zid} together with reported fitted power laws that include additional data points below 10~GHz (not shown.) The solid lines show the effect of photon-axion conversion for $m_a\leq 10^{-8}$~eV and $g_{a\gamma} = 3\times 10^{-12}\,{\rm GeV}^{-1}$.$ $Sensitivity region on photon-ALP resonant conversion bounded by the solid (dashed) red line based on the assumption that a 20\% (5\%) spectral feature can be detected. Astrophysical constraints are cumulatively shown by the blue shaded region labeled ``high energy astrophysics'' (see~\cite{githublimits}) from magnetic white dwarfs (MWD)~\cite{Dessert:2022yqq} \revplb{and pulsar polar caps~\cite{Noordhuis:2022ljw}.} Laboratory limits from CAST~\cite{CAST:2017uph}, SHAFT~\cite{Gramolin:2020ict}, ABRACADABRA~\cite{Salemi:2021gck} and projections for ALPS-II~\cite{Ortiz:2020tgs}, IAXO(+)~\cite{2013ITAS...23T0604S}, DANCE~\cite{Michimura:2019qxr}, and ADBC~\cite{Liu:2018icu} are shown as labeled. Additional constraints that assume ALPs being DM are from haloscopes~\cite{PhysRevLett.59.839,HAYSTAC:2018rwy,ADMX:2019uok,HAYSTAC:2020kwv,Jeong:2020cwz,Lee:2020cfj,ADMX:2021nhd}, previous analyses using neutron stars~\cite{Foster:2020pgt,Darling:2020plz,Battye:2021yue}, \revplb{or axion stars~\cite{Escudero:2023vgv}}.$ Show more plots

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Zapis kreiran 2023-10-26, zadnja izmjena 2024-04-30

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