The LOFAR sub-arcsecond view of the high-redshift radio relic in PSZ2G091.83+26.11

TL;DR

This study uses high-resolution LOFAR and VLA observations to analyze a distant galaxy cluster's radio relic, revealing detailed properties of particle acceleration, magnetic fields, and potential redshift evolution.

Contribution

First sub-arcsecond resolution low-frequency imaging of a high-redshift radio relic, resolving acceleration sites and magnetic field structures in unprecedented detail.

Findings

Confirmed the diffuse emission is not a radio galaxy.

Detected a spectral index gradient toward the cluster center.

Identified a shock discontinuity linked to magnetic field changes.

Abstract

Enhanced inverse Compton (IC) losses at high redshift steepen diffuse radio spectra in galaxy clusters, making low-frequency (~100 MHz) observations favorable. However, low-frequency studies often lack the resolution needed to locate particle acceleration sites or separate diffuse emission from radio galaxies. In this paper, we unveil the properties of the radio relic in the distant cluster PSZ2G091.83+26.11 (z=0.822) by resolving the acceleration site and inspecting the downstream region. Using the European LOFAR (ILT) at 145 MHz, we study a radio relic at (sub-)arcsecond resolution for the first time below 1 GHz, complemented by arcsecond-resolution VLA data at higher frequencies. We confirm the diffuse emission is not a radio galaxy. A spectral index gradient toward the cluster center matches previous 5'' maps. High-resolution 0.4'' and 1.9'' images reveal emission ahead of the shock, connecting the relic to a radio galaxy. 1.9'' profiles across the downstream at 145 MHz and 3.0 GHz follow a log-normal magnetic field distribution. The 145 MHz shock surface shows a sharp discontinuity at the same location of a change in electron density, Rotation Measure, and fractional polarization, likely tied to magnetic field changes. Finally, we find hints of redshift evolution of the radio power versus cluster mass correlation. The impressive angular resolution achievable by the LOFAR long baselines is opening an unprecedented view of the low energetic plasma in galaxy clusters. This is extremely significant in the case of high-redshift clusters, where radio emission at low frequencies is less affected by energy losses but its detection is strongly limited by poor resolution.