Detecting axion stars with radio telescopes

Detecting axion stars with radio telescopes

When axion stars fly through an astrophysical magnetic background, the axion-to-photon conversion may generate a large electromagnetic radiation power. After including the interference effects of the spacially-extended axion-star source and the macroscopic medium effects, we estimate the radiation p...

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Main Authors: Yang Bai, Yuta Hamada
Format: Article
Language:English
Published: Elsevier 2018-06-01
Series:Physics Letters B
Online Access:http://www.sciencedirect.com/science/article/pii/S0370269318302661
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spelling doaj-14aa691b88e94d30a229a11e6caa7b5a2020-11-24T23:07:50ZengElsevierPhysics Letters B0370-26932018-06-01781187194Detecting axion stars with radio telescopesYang Bai0Yuta Hamada1Department of Physics, University of Wisconsin-Madison, Madison, WI 53706, USADepartment of Physics, University of Wisconsin-Madison, Madison, WI 53706, USA; KEK Theory Center, IPNS, KEK, Tsukuba, Ibaraki 305-0801, Japan; Corresponding author.When axion stars fly through an astrophysical magnetic background, the axion-to-photon conversion may generate a large electromagnetic radiation power. After including the interference effects of the spacially-extended axion-star source and the macroscopic medium effects, we estimate the radiation power when an axion star meets a neutron star. For a dense axion star with 10−13M⊙, the radiated power is at the order of 1011W×(100μeV/ma)4(B/1010Gauss)2 with ma as the axion particle mass and B the strength of the neutron star magnetic field. For axion stars occupy a large fraction of dark matter energy density, this encounter event with a transient O(0.1s) radio signal may happen in our galaxy with the averaged source distance of one kiloparsec. The predicted spectral flux density is at the order of μJy for a neutron star with B∼1013 Gauss. The existing Arecibo, GBT, JVLA and FAST and the ongoing SKA radio telescopes have excellent discovery potential of dense axion stars.http://www.sciencedirect.com/science/article/pii/S0370269318302661
collection DOAJ
language English
format Article
sources DOAJ
author Yang Bai
Yuta Hamada
spellingShingle Yang Bai
Yuta Hamada
Detecting axion stars with radio telescopes
Physics Letters B
author_facet Yang Bai
Yuta Hamada
author_sort Yang Bai
title Detecting axion stars with radio telescopes
title_short Detecting axion stars with radio telescopes
title_full Detecting axion stars with radio telescopes
title_fullStr Detecting axion stars with radio telescopes
title_full_unstemmed Detecting axion stars with radio telescopes
title_sort detecting axion stars with radio telescopes
publisher Elsevier
series Physics Letters B
issn 0370-2693
publishDate 2018-06-01
description When axion stars fly through an astrophysical magnetic background, the axion-to-photon conversion may generate a large electromagnetic radiation power. After including the interference effects of the spacially-extended axion-star source and the macroscopic medium effects, we estimate the radiation power when an axion star meets a neutron star. For a dense axion star with 10−13M⊙, the radiated power is at the order of 1011W×(100μeV/ma)4(B/1010Gauss)2 with ma as the axion particle mass and B the strength of the neutron star magnetic field. For axion stars occupy a large fraction of dark matter energy density, this encounter event with a transient O(0.1s) radio signal may happen in our galaxy with the averaged source distance of one kiloparsec. The predicted spectral flux density is at the order of μJy for a neutron star with B∼1013 Gauss. The existing Arecibo, GBT, JVLA and FAST and the ongoing SKA radio telescopes have excellent discovery potential of dense axion stars.
url http://www.sciencedirect.com/science/article/pii/S0370269318302661
work_keys_str_mv AT yangbai detectingaxionstarswithradiotelescopes
AT yutahamada detectingaxionstarswithradiotelescopes
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