Observing the thermalization of dark matter in neutron stars

A promising probe to unmask particle dark matter is to observe its effect on neutron stars, the prospects of which depend critically on whether captured dark matter thermalizes in a timely manner with the stellar core via repeated scattering with the Fermi-degenerate medium. In this work we estimate the timescales for thermalization for multiple scenarios. These include: (a) spin-0 and spin 1/2 dark matter, (b) scattering on nonrelativistic neutron and relativistic electron targets accounting for the respective kinematics, (c) interactions via a range of Lorentz-invariant structures, (d) mediators both heavy and light in comparison to the typical transfer momenta in the problem. We discuss the analytic behavior of the thermalization time as a function of the dark matter and mediator masses, and the stellar temperature. Finally, we identify parametric ranges where both stellar capture is efficient and thermalization occurs within the age of the universe. For dark matter that can annihilate in the core, these regions indicate parametric ranges that can be probed by upcoming infrared telescopes observing cold neutron stars.

Automated summary

This study investigates the timescales for thermalization of dark matter in neutron stars under different scenarios, analyzing the effects of various factors such as dark matter and mediator masses, stellar temperature, and interaction structures. The results identify parametric ranges where efficient stellar capture and thermalization within the age of the universe occur, suggesting areas that can be probed by upcoming infrared telescopes observing cold neutron stars.