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Rapidly spinning dark matter-admixed neutron stars

Authors: Cipriani, L.; Giangrandi, E.; Sagun, V.; Doneva, D.D.; Yazadjiev, S.S.

Ref.: Phys. Rev. D 111(12), 123005 (2025)

Abstract: Millisecond pulsars, representing the older neutron star population, are believed to have undergone a prolonged period of dark matter accumulation, resulting in a higher dark matter content. Their extreme rotation makes them unique laboratories for studying rapidly rotating neutron stars admixed with dark matter. In this work, we model uniformly rotating neutron stars with a dark matter component that rotates independently from the baryon matter, allowing for the investigation of both corotating and counterrotating scenarios. We examine the impact of dark matter rotation on the macroscopic properties of neutron stars, including the mass-radius relation, the mass-shedding Keplerian limit, and moments of inertia, for various dark matter particle masses and total fractions, considering both core and halo distributions. Our findings provide a more comprehensive understanding of how dark matter influences the equilibrium properties of rotating neutron stars, offering new insights into the astrophysical implications of self-interacting dark matter.

DOI: 10.1103/qcl7-m5kf