High Resolution Imaging of the Magnetic Field in the central parsec of the Galaxy

TL;DR

This study provides high-resolution mid-infrared polarization imaging of the Galactic Centre's minispiral, revealing detailed magnetic field structures and their relation to dust, stars, and orbital motions.

Contribution

It offers new high-resolution polarization data that uncovers complex magnetic field geometries and their interaction with stellar and dust structures in the Galactic Centre.

Findings

Magnetic fields are coherent and aligned with dust filaments.

Stars do not disrupt the magnetic field, indicating wind compression.

Weak correlation between emission intensity and polarization degree.

Abstract

We discuss a high resolution (FWHM~ 0.45 arcsec) image of the emissive polarization from warm dust in the minispiral in the Galactic Centre and discuss the implications for the magnetic field in the dusty filaments. The image was obtained at a wavelength of 12.5 microns with the CanariCam multimode mid-infrared imager on the Gran Telescopio Canarias. It confirms the results obtained from previous observations but also reveals new details of the polarization structures. In particular, we identify regions of coherent magnetic field emission at position angles of ~45 deg to the predominantly north--south run of field lines in the Northern Arm which may be related to orbital motions inclined to the general flow of the Northern Arm. The luminous stars that have been identified as bow-shock sources in the Northern Arm do not disrupt or dilute the field but are linked by a coherent field structure, implying that the winds from these objects may push and compress the field but do not overwhelm it. The magnetic field in the the low surface brightness regions in the East-West Bar to the south of SgrA* lies along the Bar, but the brighter regions generally have different polarization position angles, suggesting that they are distinct structures. In the region of the Northern Arm sampled here, there is only a weak correlation between the intensity of the emission and the degree of polarization. This is consistent with saturated grain alignment where the degree of polarization depends on geometric effects, including the angle of inclination of the field to the line of sight and superposition of filaments with different field directions, rather than the alignment efficiency.