Deep observation of the NGC 1275 region with MAGIC: search of diffuse gamma-ray emission from cosmic rays in the Perseus cluster

TL;DR

This study used MAGIC telescopes to observe the Perseus galaxy cluster, detecting gamma-ray emissions from NGC 1275 but not from the cluster itself, thus constraining cosmic ray populations and magnetic fields.

Contribution

First detailed VHE gamma-ray measurement of NGC 1275 and the most stringent limits on diffuse gamma-ray emission from the Perseus cluster to date.

Findings

NGC 1275 spectrum fits a power law with photon index 3.6 between 90 GeV and 1.2 TeV.

No diffuse gamma-ray emission detected from the cluster, constraining cosmic ray pressure to below 1-2%.

Lower limits on central magnetic field strength derived, challenging some hadronic models.

Abstract

Clusters of galaxies are expected to be reservoirs of cosmic rays (CRs) that should produce diffuse gamma-ray emission due to their hadronic interactions with the intra-cluster medium. The nearby Perseus cool-core cluster, identified as the most promising target to search for such an emission, has been observed with the MAGIC telescopes at very-high energies (VHE, E>100 GeV) for a total of 253 hr from 2009 to 2014. The active nuclei of NGC 1275, the central dominant galaxy of the cluster, and IC 310, lying at about 0.6$^\circ$ from the centre, have been detected as point-like VHE gamma-ray emitters during the first phase of this campaign. We report an updated measurement of the NGC 1275 spectrum, which is well described by a power law with a photon index of $3.6\pm0.2_{stat}\pm0.2_{syst}$ between 90 GeV and 1.2 TeV. We do not detect any diffuse gamma-ray emission from the cluster and set stringent constraints on its CR population. In order to bracket the uncertainties over the CR spatial and spectral distributions, we adopt different spatial templates and power-law spectral indexes $\alpha$. For $\alpha=2.2$, the CR-to-thermal pressure within the cluster virial radius is constrained to be below 1-2%, except if CRs can propagate out of the cluster core, generating a flatter radial distribution and releasing the CR-to-thermal pressure constraint to <20%. Assuming that the observed radio mini-halo of Perseus is generated by secondary electrons from CR hadronic interactions, we can derive lower limits on the central magnetic field, $B_0$, that depend on the CR distribution. For $\alpha=2.2$, $B_0\gtrsim5-8 \mu$G, which is below the 25 $\mu$G inferred from Faraday rotation measurements, whereas, for $\alpha\lesssim2.1$, the hadronic interpretation of the diffuse radio emission is in contrast with our gamma-ray flux upper limits independently of the magnetic field strength.