Abstract
We propose a dark-matter (DM) admixed density-dependent equation of state where the fermionic DM interacts with the nucleons via Higgs portal. Presence of DM can hardly influence the particle distribution inside neutron star (NS) but can significantly affect the structure as well as equation of state (EOS) of NS. Introduction of DM inside NS softens the equation of state. We explored the effect of variation of DM mass and DM Fermi momentum on the NS EOS. Moreover, DM-Higgs coupling is constrained using dark matter direct detection experiments. Then, we studied cooling of normal NSs using APR and DD2 EOSs and DM admixed NSs using dark-matter modified DD2 with varying DM mass and Fermi momentum. We have done our analysis by considering different NS masses. Also DM mass and DM Fermi momentum are varied for fixed NS mass and DM-Higgs coupling. We calculated the variations of luminosity and temperature of NS with time for all EOSs considered in our work and then compared our calculations with the observed astronomical cooling data of pulsars namely Cas A, RX J0822-43, 1E 1207-52, RX J0002+62, XMMU J17328, PSR B1706-44, Vela, PSR B2334+61, PSR B0656+14, Geminga, PSR B1055-52 and RX J0720.4-3125. It is found that APR EOS agrees well with the pulsar data for lighter and medium mass NSs but cooling is very fast for heavier NS. For DM admixed DD2 EOS, it is found that for all considered NS masses, all chosen DM masses and Fermi momenta agree well with the observational data of PSR B0656+14, Geminga, Vela, PSR B1706-44 and PSR B2334+61. Cooling becomes faster as compared to normal NSs in case of increasing DM mass and Fermi momenta. It is infered from the calculations that if low mass super cold NSs are observed in future that may support the fact that heavier WIMP can be present inside neutron stars.
Highlights
Neutron stars are excellent celestial laboratories for investigating the supradense nuclear matter which is otherwise inaccessible to terrestrial laboratories
We have considered the complete set of cooling data of both young and cool and old and warm neutron stars namely Cassiopi A (Cas A), RX J0822-43, 1E 1207-52, RX J0002+62, XMMU J17328, PSR B1706-44, Vela, PSR B2334+61, PSR B0656+14, Geminga, PSR B1055-52 and RX J0720.4-3125
We studied neutron star (NS) cooling of both normal NSs using DD2 equation of state (EOS) [43,44] and Akmal-Pandharipande-Ravenhall (APR) EOS [54] and Dark matter (DM) admixed NSs using DD2 EOS modified with DM sector
Summary
Neutron stars are excellent celestial laboratories for investigating the supradense nuclear matter which is otherwise inaccessible to terrestrial laboratories. Exotic particles soften the equation of state (EOS) and reduce the tidal deformability of the neutron star [9]. It has been shown that fermionic DM could soften the equation of state and reduce the maximum mass supported by the NS [7] This effect is sensitive to the mass of DM particle and the selfinteraction within the dark matter. [40], the authors have studied the cooling of DM admixed NS with dark matter mass ranging from 0.1 GeV to. We have considered low as well as high dark matter masses (upto 500 GeV) and varied the dark matter Fermi momenta for the cooling calculations For these calculations, we have considered dark-matter modified density-dependent (DD2) EOS [43,44] and the results are compared with the observational data.
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