Amplified J-factors in the Galactic Center for velocity-dependent darkmatter annihilation in FIRE simulations

TL;DR

This study uses FIRE-2 simulations to calculate astrophysical J-factors for dark matter annihilation, revealing significant enhancements in velocity-dependent models, especially p-wave, which could impact indirect detection efforts.

Contribution

It provides the first detailed calculation of velocity-dependent J-factors in FIRE simulations, highlighting the importance of baryonic physics on dark matter annihilation signals.

Findings

FIRE simulations show higher central dark matter velocity dispersions than DMO.

J-factors for velocity-dependent models are significantly increased in FIRE runs.

P-wave annihilation signals could be detectable with upcoming experiments.

Abstract

We use FIRE-2 zoom cosmological simulations of Milky Way size galaxy halos to calculate astrophysical J-factors for dark matter annihilation and indirect detection studies. In addition to velocity-independent (s-wave) annihilation cross sections $\sigma_v$, we also calculate effective J-factors for velocity-dependent models, where the annihilation cross section is either either p-wave ($\propto v^2/c^2$) or d-wave ($\propto v^4/c^4$). We use 12 pairs of simulations, each run with dark-matter-only (DMO) physics and FIRE-2 physics. We observe FIRE runs produce central dark matter velocity dispersions that are systematically larger than in DMO runs by factors of $\sim 2.5-4$. They also have a larger range of central ($\sim 400$ pc) dark matter densities than the DMO runs ($\rho_{\rm FIRE}/\rho_{\rm DMO} \simeq 0.5 - 3$) owing to the competing effects of baryonic contraction and feedback. At 3 degrees from the Galactic Center, FIRE J-factors are $5-50$ (p-wave) and $15-500$ (d-wave) times higher than in the DMO runs. The change in s-wave signal at 3 degrees is more modest and can be higher or lower ($\sim 0.3-6$), though the shape of the emission profile is flatter (less peaked towards the Galactic Center) and more circular on the sky in FIRE runs. Our results for s-wave are broadly consistent with the range of assumptions in most indirect detection studies. We observe p-wave J-factors that are significantly enhanced compared to most past estimates. We find that thermal models with p-wave annihilation may be within range of detection in the near future.