# CHAMP Cosmic Rays

**Authors:** David Dunsky, Lawrence J. Hall, Keisuke Harigaya

arXiv: 1812.11116 · 2019-07-12

## TL;DR

This paper investigates the behavior and detection prospects of cosmological relic particles with electric charge, analyzing their acceleration, flux, and experimental bounds, and identifying parameter regions accessible to future searches.

## Contribution

It provides a comprehensive analysis of charged relics' acceleration, flux, and detection constraints, highlighting new parameter space regions for future experiments.

## Key findings

- Accelerated relic flux extends to high energies up to ~5×10^4 q GeV.
- Strong bounds on relics as dark matter exclude q > 10^{-9} for any mass.
- Future experiments can probe specific (mass, charge) regions of relic parameter space.

## Abstract

We study interactions of cosmological relics, $X$, of mass $m$ and electric charge $qe$ in the galaxy, including thermalization with the interstellar medium, diffusion through inhomogeneous magnetic fields and Fermi acceleration by supernova shock waves. We find that for $m \mathop{}_{\textstyle \sim}^{\textstyle <} 10^{10} q \; ~{\rm GeV}$, there is a large flux of accelerated $X$ in the disk today, with a momentum distribution $\propto 1/p^{2.5}$ extending to $(\beta p)_{max} \sim 5 \times10^4 q \; ~{\rm GeV}$. Even though acceleration in supernova shocks is efficient, ejecting $X$ from the galaxy, $X$ are continually replenished by diffusion into the disk from the halo or confinement region. For $m \mathop{}_{\textstyle \sim}^{\textstyle >} 10^{10} q \; ~{\rm GeV}$, $X$ cannot be accelerated above the escape velocity within the lifetime of the shock. The accelerated $X$ form a component of cosmic rays that can easily reach underground detectors, as well as deposit energies above thresholds, enhancing signals in various experiments. We find that nuclear/electron recoil experiments place very stringent bounds on $X$ at low $q$; for example, $X$ as dark matter is excluded for $q$ above $10^{-9}$ for any $m$. For larger $q$, stringent bounds on the fraction of dark matter that can be $X$ are set by Cherenkov and ionization detectors. Nevertheless, very small $q$ is highly motivated by the kinetic mixing portal, and we identify regions of $(m,q)$ that can be probed by future experiments.

## Full text

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## Figures

24 figures with captions in the complete paper: https://tomesphere.com/paper/1812.11116/full.md

## References

84 references — full list in the complete paper: https://tomesphere.com/paper/1812.11116/full.md

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Source: https://tomesphere.com/paper/1812.11116