2019
DOI: 10.1088/1475-7516/2019/06/054
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Capture of leptophilic dark matter in neutron stars

Abstract: Dark matter particles will be captured in neutron stars if they undergo scattering interactions with nucleons or leptons. These collisions transfer the dark matter kinetic energy to the star, resulting in appreciable heating that is potentially observable by forthcoming infrared telescopes. While previous work considered scattering only on nucleons, neutron stars contain small abundances of other particle species, including electrons and muons. We perform a detailed analysis of the neutron star kinetic heating… Show more

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Cited by 105 publications
(104 citation statements)
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“…NSs with masses of order a solar mass subsequently have 0.15%-0.75% of their mass stored in muons, providing a unique laboratory to test couplings of muons to light new degrees of freedom. This has been leveraged to place constraints on muon-philic dark matter due to its accretion in NSs [45,63,64].…”
Section: Introductionmentioning
confidence: 99%
“…NSs with masses of order a solar mass subsequently have 0.15%-0.75% of their mass stored in muons, providing a unique laboratory to test couplings of muons to light new degrees of freedom. This has been leveraged to place constraints on muon-philic dark matter due to its accretion in NSs [45,63,64].…”
Section: Introductionmentioning
confidence: 99%
“…Others have calculated the effect of this accumulated dark matter on cooling of celestial objects [34][35][36][37], or have compared the dark luminosity with the observed luminosity to provide stringent constraints on dark matter interactions with SM particles [35,38,39]. More recently, limits on DM-nucleon cross section have also been obtained from non-observation of collapse of massive white dwarfs [40] or from neutron star heating [41][42][43][44].…”
Section: Introductionmentioning
confidence: 99%
“…In the case where DM is partially or purely symmetric, which occurs for smaller values of m N and g s in our model (recall figure 1), the accumulated DM inside the NS core can annihilate and the annihilation products might thermalize, heating up the star and contributing to its luminosity [94,99]. The latter is also increased by DM kinetic heating from multiple DM scatterings with the NS constituents, namely neutrons, electrons and muons, and this effect is independent of whether the DM is symmetric or asymmetric [99,100]. However, the expected NS surface temperature generated only by DM annihilation and scattering is too low to be detected by current infrared telescopes.…”
Section: Dm Indirect Detectionmentioning
confidence: 71%