Investigation of the cosmic ray population and magnetic field strength in the halo of NGC 891

TL;DR

This study combines multi-frequency radio observations of NGC 891 to analyze cosmic-ray electrons and magnetic fields, revealing spectral aging effects, magnetic field strengths, and dominant cosmic-ray transport mechanisms in the galaxy's halo.

Contribution

It provides new low-frequency LOFAR observations and comprehensive analysis of cosmic-ray propagation and magnetic fields in NGC 891's halo, highlighting the importance of spectral aging and transport processes.

Findings

Mean magnetic field in halo: 7 ± 2 μG

Halo scale heights are larger at lower frequencies

Spectral index steepens from disk to halo

Abstract

Low-frequency radio continuum observations of edge-on galaxies are ideal to study cosmic-ray electrons (CREs) in halos via radio synchrotron emission and to measure magnetic field strengths. We obtained new observations of the edge-on spiral galaxy NGC 891 at 129-163 MHz with the LOw Frequency ARray (LOFAR) and at 13-18 GHz with the Arcminute Microkelvin Imager (AMI) and combine them with recent high-resolution Very Large Array (VLA) observations at 1-2 GHz, enabling us to study the radio continuum emission over two orders of magnitude in frequency. The spectrum of the integrated nonthermal flux density can be fitted by a power law with a spectral steepening towards higher frequencies or by a curved polynomial. Spectral flattening at low frequencies due to free-free absorption is detected in star-forming regions of the disk. The mean magnetic field strength in the halo is 7 +- 2 $\mu$G. The scale heights of the nonthermal halo emission at 146 MHz are larger than those at 1.5 GHz everywhere, with a mean ratio of 1.7 +- 0.3, indicating that spectral ageing of CREs is important and that diffusive propagation dominates. The halo scale heights at 146 MHz decrease with increasing magnetic field strengths which is a signature of dominating synchrotron losses of CREs. On the other hand, the spectral index between 146 MHz and 1.5 GHz linearly steepens from the disk to the halo, indicating that advection rather than diffusion is the dominating CRE transport process. This issue calls for refined modelling of CRE propagation.