Cosmic ray diffusion fronts in the Virgo cluster

TL;DR

This paper models the sharp radio edges of Virgo cluster lobes using steady-state cosmic ray diffusion fronts, linking magnetic field alignment, radio emission, and gas dynamics to explain observed features.

Contribution

It introduces a detailed steady diffusion front model that explains radio limb-brightening and predicts observable effects on magnetic fields and gas density in galaxy clusters.

Findings

Diffusion fronts explain sharp radio edges and limb-brightening.

Magnetic field alignment reduces electron diffusion, affecting radio emission.

Potential X-ray signatures of cosmic ray pressure effects.

Abstract

The pair of large radio lobes in the Virgo cluster, each about 23 kpc in radius, have curiously sharp outer edges where the radio-synchrotron continuum flux declines abruptly. However, just adjacent to this sharp transition, the radio flux increases. This radio limb-brightening is observed over at least half of the perimeter of both lobes. We describe slowly propagating steady state diffusion fronts that explain these counterintuitive features. Because of the natural buoyancy of radio lobes, the magnetic field is largely tangent to the lobe boundary, an alignment that polarizes the radio emission and dramatically reduces the diffusion coefficient of relativistic electrons. As cosmic ray electrons diffuse slowly into the cluster gas, the local magnetic field and gas density are reduced as gas flows back toward the radio lobe. Radio emission peaks can occur because the synchrotron emissivity increases with magnetic field and then decreases with the density of non-thermal electrons. A detailed comparison of steady diffusion fronts with quantitative radio observations may reveal information about the spatial variation of magnetic fields and the diffusion coefficient of relativistic electrons. On larger scales, some reduction of the gas density inside the Virgo lobes due to cosmic ray pressure must occur and may be measurable. Such X-ray observations could reveal important information about the presence of otherwise unobservable non-thermal components such as relativistic electrons of low energy or proton cosmic rays.