Abell 0399-Abell 0401 radio bridge spectral index: the first multifrequency detection

TL;DR

This study presents the first multifrequency detection of the radio bridge between galaxy clusters Abell 0399 and Abell 0401, revealing a steepening spectrum that informs models of particle acceleration and magnetic fields on large scales.

Contribution

It provides the first spectral index map of a radio bridge and combines low-frequency observations with theoretical models to understand particle re-acceleration mechanisms.

Findings

Detected the radio bridge at 60 MHz with LOFAR LBA.

Measured an integrated spectral index of -1.44 ± 0.16 between 60 and 144 MHz.

Observed spectral steepening above 144 MHz consistent with turbulent re-acceleration.

Abstract

Recent low-frequency radio observations at 140 MHz discovered a 3 Mpc-long bridge of diffuse emission connecting the galaxy clusters Abell 0399 and Abell 0401. We present follow-up observations at 60 MHz to constrain the spectral index of the bridge, which so far has only been detected at 140 and 144 MHz. We analysed deep (~18 hours) LOw Frequency ARray (LOFAR) Low Band Antenna (LBA) data at 60 MHz to detect the bridge at very low frequencies. We then conducted a multi-frequency study with LOFAR HBA data at 144 MHz and uGMRT data at 400 MHz. Assuming second-order Fermi mechanisms for the re-acceleration of relativistic electrons driven by turbulence in the radio bridge regions, we compare the observed radio spectrum with theoretical synchrotron models. The bridge is detected in the 75'' resolution LOFAR image at 60 MHz and its emission fully connects the region between the two galaxy clusters. Between 60 MHz and 144 MHz we found an integrated spectral index value of -1.44 +\- 0.16 for the bridge emission. For the first time, we produced spectral index and related uncertainties maps for a radio bridge. We produce a radio spectrum, which show significant steepening between 144 and 400 MHz. This detection at low frequencies provides important information on the models of particle acceleration and magnetic field structure on very extended scales. The spectral index gives important clues to the origin of inter-cluster diffuse emission. The steepening of the spectrum above 144 MHz can be explained in a turbulent re-acceleration framework, assuming that the acceleration timescales are longer than ~200 Myr.