Cumulative Neutrino and Gamma-Ray Backgrounds from Halo and Galaxy Mergers

TL;DR

This paper investigates how halo and galaxy mergers produce high-energy neutrinos and gamma rays, potentially explaining IceCube's neutrino observations and fitting within gamma-ray background constraints.

Contribution

It models the contribution of halo mergers to diffuse neutrino and gamma-ray backgrounds, incorporating redshift evolution and shock physics, providing a new explanation for observed high-energy cosmic phenomena.

Findings

High-redshift mergers significantly contribute to neutrino flux above 0.1 PeV.

Model can explain a large part of IceCube's diffuse neutrino flux.

Gamma-ray emission is suppressed by interactions with CMB and EBL, alleviating tension with Fermi data.

Abstract

The merger of dark matter halos and the gaseous structures embedded in them, such as proto-galaxies, galaxies, and groups and clusters of galaxies, results in strong shocks that are capable of accelerating cosmic rays (CRs) to $\sim10~\rm PeV$. These shocks will produce high-energy neutrinos and $\gamma$-rays through inelastic $pp$ collisions with ambient gaseous environments. In this work, we study the contributions of these halo mergers to the diffuse neutrino flux measured in IceCube and to the non-blazar portion of the extragalactic $\gamma$-ray background measured by $Fermi$. In order to calculate them, we formulate the redshift dependence of the shock velocity, galactic radius, halo gas content and galactic/intergalactic magnetic fields over the dark matter halo distribution up to a redshift $z=10$. We find that high-redshift mergers contribute a significant amount of the cosmic-ray energy luminosity density, and the resulting neutrino spectra could explain a large part of the observed diffuse neutrino flux above 0.1 PeV up to several PeV. We also show that our model can somewhat alleviate tensions with the extragalactic $\gamma$-ray background. First, since a larger fraction of the CR energy luminosity density comes from high redshifts, the accompanying $\gamma$-rays are more strongly suppressed through $\gamma\gamma$ annihilations with the cosmic microwave background (CMB) and the extragalactic background light (EBL). Second, mildly radiative-cooled shocks may lead to a harder CR spectrum with spectral indices of $1.5\lesssim s\lesssim2.0$. Our study suggests that halo mergers, a fraction of which may also induce starbursts in the merged galaxies, can be promising neutrino emitters without violating the existing $Fermi$ $\gamma$-ray constraints on the non-blazar component of the extragalactic $\gamma$-ray background.