# Shock Acceleration Model for the Toothbrush Radio Relic

**Authors:** Hyesung Kang, Dongsu Ryu, T. W. Jones

arXiv: 1703.00171 · 2017-06-06

## TL;DR

This paper investigates the origin of the Toothbrush radio relic by comparing weak and strong shock models, incorporating turbulent acceleration, and finds strong-shock models with low-energy seed electrons are more plausible.

## Contribution

It introduces a comprehensive analysis of DSA models including turbulent acceleration to explain the relic's properties, favoring strong-shock scenarios with low-energy seed electrons.

## Key findings

- Both models fit the integrated radio spectrum well.
- Turbulent acceleration explains the broad transverse profile.
- Strong-shock models with low-energy seed electrons are preferred.

## Abstract

Although many of the observed properties of giant radio relics detected in the outskirts of galaxy clusters can be explained by relativistic electrons accelerated at merger-driven shocks, significant puzzles remain. In the case of the so-called Toothbrush relic, the shock Mach number estimated from X-ray observations ($M_{\rm X}\approx1.2-1.5$) is substantially weaker than that inferred from the radio spectral index ($M_{\rm rad}\approx2.8$).Toward understanding such a discrepancy, we here consider the following diffusive shock acceleration (DSA) models:(1) weak-shock models with $M_{\rm s}\lesssim 2$ and a preexisting population of cosmic-ray electrons (CRe) with a flat energy spectrum,and (2) strong-shock models with $M_{\rm s}\approx3$ and either shock-generated suprathermal electrons or preexisting fossil CRe. We calculate the synchrotron emission from the accelerated CRe, following the time evolution of the electron DSA, and subsequent radiative cooling and postshock turbulent acceleration (TA). We find that both models could reproduce reasonably well the observed integrated radio spectrum of the Toothbrush relic, but the observed broad transverse profile requires the stochastic acceleration by downstream turbulence, which we label "turbulent acceleration" or TA to distinguish it from DSA. Moreover, to account for the almost uniform radio spectral index profile along the length of the relic, the weak-shock models require a preshock region over 400~kpc with a uniform population of preexisting CRe with a high cutoff energy ($\gtrsim 40$ GeV). Due to the short cooling time, it is challenging to explain the origin of such energetic electrons. Therefore, we suggest the strong-shock models with low-energy seed CRe ($\lesssim 150$~MeV) are preferred for the radio observations of this relic.

## Full text

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## Figures

10 figures with captions in the complete paper: https://tomesphere.com/paper/1703.00171/full.md

## References

54 references — full list in the complete paper: https://tomesphere.com/paper/1703.00171/full.md

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Source: https://tomesphere.com/paper/1703.00171