Implications of Fermionic Dark Matter Interactions on Anisotropic Neutron Stars

TL;DR

This paper investigates how fermionic dark matter interactions affect the properties of anisotropic neutron stars, using various equations of state and observational data to understand their structure and potential observational signatures.

Contribution

It introduces a comprehensive analysis of anisotropic neutron stars with dark matter admixture, considering multiple EOS and observational constraints, highlighting the impact of dark matter coupling on star properties.

Findings

Higher anisotropies can satisfy observational constraints with increased dark matter fractions.

Dark matter coupling leads to core-halo structures in neutron stars.

Maximum radius decreases with anisotropy at higher dark matter couplings.

Abstract

The presence of Dark matter (DM) within a neutron star (NS) can substantially influence the macroscopic properties. It is commonly assumed that the pressure inside an NS is isotropic, but in reality, pressure is locally anisotropic. This study explores the properties of anisotropic NS with a subfraction of DM (isotropic) trapped inside. Implementing a two-fluid formalism with three Equations of State (EOS): AP3 (a realistic nucleon-nucleon interaction model), BSk22 (modeling atomic nuclei and neutron-matter), and MPA1 (considering relativistic effects in nuclear interactions). The properties of NS, such as mass ($M$), radius ($R$), and dimensionless tidal deformability ($\Lambda$), for various DM-anisotropic configurations, have been rigorously tested against observational constraints. These constraints include data from the binary NS merger GW170817, NICER x-ray measurements, and pulsar mass-radius observations. We observe that with increasing DM subfraction, higher anisotropies could also satisfy the observational constraints. Furthermore, increasing the coupling ($g$) between DM and its mediator leads to the formation of a core-halo structure, with a DM halo surrounding the baryonic matter (BM). Specifically, for coupling values of $g = 10^{-4}$, $10^{-3.7}$, and $10^{-3.5}$, we observe that the maximum radius ($R_{max}$) decreases with increasing anisotropy, which contrasts with the behavior at $g = 10^{-5}$ and in scenarios with no DM. Our analysis indicates that binary pulsar systems could potentially constrain the extent of admixed anisotropic NS or, more optimistically, provide evidence for the existence of DM-admixed anisotropic NS.