http://arxiv.org/abs/1403.6743
We present simulations of a radio minihalo in a galaxy cluster core with sloshing cold fronts, under the assumption that the source of the synchrotron-emitting electrons is hadronic interactions between cosmic-ray protons with the thermal intracluster gas. This is an alternative to the hypothesis where the cosmic ray electrons are reaccelerated by the intracluster turbulence, which we have discussed in an earlier work. We follow the evolution of cosmic-ray electron spectra associated with passive tracer particles, taking into account the time-dependent injection of new electrons from the hadronic interactions and energy losses along each particle’s trajectory. We then simulate the radio emission from these particles. The drop in radio emission at the cold front surfaces is less prominent than that in our previous simulations, based on electron reacceleration from sloshing-induced turbulence, where the emission is definitively confined to the regions within cold fronts. The result is that the emission is overall more spatially extended than found in some observed minihalos. We also explore spectral effects induced by the change of physical conditions in the ICM. Rapid changes in magnetic field strength are expected to produce radio spectra steeper than those calculated assuming stationary conditions, but we find this effect is marginal, with differences in the synchrotron spectral index $\Delta{\alpha}$ < 0.15 between $\nu\sim$ 300-1400 MHz and $\Delta{\alpha}$ < 0.25 between $\nu\sim$ 60-153 MHz.
J. ZuHone, G. Brunetti, S. Giacintucci, et. al.
Thu, 27 Mar 14
58/62
You must be logged in to post a comment.