2020
DOI: 10.1088/1361-6471/ab9d36
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GW170817 constraints on the properties of a neutron star in the presence of WIMP dark matter

Abstract: The properties of a neutron star are studied in the presence of dark matter. We have considered a relatively light weakly interacting massive particle (WIMP) as a dark matter candidate with properties suggested by the results of the DAMA/LIBRA collaboration, realized for instance within the framework of the Next-to-Minimal Supersymmetric Standard Model. The dark matter particle interacts with the baryonic matter of a neutron star through Higgs bosons. The dark matter variables are essentially fixed using the r… Show more

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Cited by 48 publications
(36 citation statements)
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References 110 publications
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“…7), astronomical observations can also be used to place constraints on the relevant parameter space. In general, since GW170817 provided an upper limit onΛ, any physical effect that results in a softening of the equation of state can be consistent with the data [88,[240][241][242][243][244][245][246] As such, a strong first-order phase transition might make an equation of state model compatible with the GW170817 data, even if the hadronic part on its own is not [152,[247][248][249][250]. A number of studies have constructed models that can successfully interpret the inspiral signal from GW170817 as the coalescence of any combination of hadronic and hybrid hadronic-quark neutron stars and place corresponding constraints on the relevant model parameter space [149,247,248,[251][252][253][254][255][256][257][258][259][260].…”
Section: Microscopic Propertiessupporting
confidence: 59%
See 1 more Smart Citation
“…7), astronomical observations can also be used to place constraints on the relevant parameter space. In general, since GW170817 provided an upper limit onΛ, any physical effect that results in a softening of the equation of state can be consistent with the data [88,[240][241][242][243][244][245][246] As such, a strong first-order phase transition might make an equation of state model compatible with the GW170817 data, even if the hadronic part on its own is not [152,[247][248][249][250]. A number of studies have constructed models that can successfully interpret the inspiral signal from GW170817 as the coalescence of any combination of hadronic and hybrid hadronic-quark neutron stars and place corresponding constraints on the relevant model parameter space [149,247,248,[251][252][253][254][255][256][257][258][259][260].…”
Section: Microscopic Propertiessupporting
confidence: 59%
“…If the tidal deformability of black holes is indeed vanishing (or if it is very small), studying tidal effects in mergers of black holes could put constraints on horizon-level spacetime corrections [81]. The tidal deformability can therefore also be used to test the nature of the coalescing compact objects [82][83][84][85][86], or other physics such as dark matter and extra dimensions [87][88][89][90].…”
Section: The Tidal Deformability Of a Black Holementioning
confidence: 99%
“…A NS has a rich spectrum of modes. Those with sufficiently low frequencies could be tidally excited during an inspiral and yield spectroscopic information about matter in NS interiors; several examples have been studied to date [27,216,270,300,317,437,448,493,528,529,561]. Effects from nonlinear mode coupling have also been studied [200,323,550].…”
Section: Other Matter Effectsmentioning
confidence: 99%
“…In this paper we investigate the effects of tidal deformations [93][94][95] on the conservative two-body Hamiltonian during the inspiral phase, focusing on their structure in the post-Minkowskian expansion. The tidal deformations offer a window into the equation of state of neutrons stars [96][97][98][99] and test our understanding of black holes [83,[100][101][102][103][104][105][106][107] and of possible exotic physics [108][109][110][111][112][113][114]. While tidal effects are expected to vanish for black holes in general relativity [97,[115][116][117][118], they are of crucial importance for understanding the equation of state of neutron stars.…”
Section: Introductionmentioning
confidence: 99%