Constraining the magnetic field in the galaxy cluster Abell 2142 using MeerKAT L-band polarisation data

TL;DR

This study uses MeerKAT L-band polarisation data to constrain the magnetic field strength, structure, and radial profile in galaxy cluster Abell 2142, revealing a decreasing magnetic field with radius and a peak at ~140 kpc.

Contribution

First polarisation imaging of Abell 2142 with MeerKAT, providing detailed magnetic field constraints through RM synthesis and comparison with 3D simulations.

Findings

Magnetic field strength at the center is approximately 9.5 μG.

Magnetic field decreases with radius, consistent with other clusters.

Magnetic power spectrum peaks at ~140 kpc.

Abstract

Magnetic fields permeate the Universe, including galaxy clusters, and affect the thermodynamical properties of the intra-cluster medium (ICM). Cosmological simulations predict that seed magnetic fields are amplified up to the $\mu$G-level in the ICM, but the magnetic field strength and structure have been studied in only a few clusters. Abell 2142 is a local massive cluster that shows evidence of a post-merger dynamical state. In this work, we aim to constrain the magnetic field intensity, radial profile and power spectrum within its ICM, providing key insights into the nature of this non-thermal component in galaxy clusters. We present MeerKAT observations of Abell 2142 in the L-band (872-1712 MHz), imaged in polarisation for the first time with this purpose. We derive the Rotation Measure (RM) from the radio galaxies' polarised emission by applying the RM synthesis technique and analyse both the RM and fractional polarisation ($\mathrm{F_p}$). To investigate the magnetic field distribution within the ICM, we compare our results with mock RM maps generated from 3D simulations of the cluster. We find that the RM dispersion, $\sigma_{\mathrm{RM}}$, decreases with projected radius, whereas the $\mathrm{F_p}$ increases. Both trends suggest that the magnetic field intensity decreases at larger distances from the cluster center, in agreement with studies on other clusters. Assuming that the magnetic field energy density scales with the gas thermal energy ($B \propto n_e^{0.5}$), a magnetic field with a power spectrum ranging from scales between 7 and 470 kpc, with peak at $\sim 140$ kpc and mean central strength of $9.5 \pm 1.0 \ \mu$G, provides the best fit to our data. The high central magnetic field lies at the upper end of the range observed in other systems and supports the possibility of an hadronic contribution to the diffuse radio emission previously detected at the cluster center.