The highly polarized dusty emission core of Cygnus A

TL;DR

This study detects highly polarized dust emission from Cygnus A at mid- to far-infrared wavelengths, revealing a dominant dust component aligned with magnetic fields, distinct from scattering mechanisms at shorter wavelengths.

Contribution

It presents the first polarization measurements at 53 and 89 μm of Cygnus A, demonstrating dust emission dominance and magnetic field alignment in the IR core.

Findings

Polarization of 11% at 53 μm and 9% at 89 μm with consistent position angles.

A blackbody dust component peaking at ~40 μm with a temperature of 107 K.

A polarization angle change of ~20° from IR to far-IR indicating different polarization mechanisms.

Abstract

We report the detection of linearly polarized emission at 53 and 89 $\mu$m, from the radio-loud active galactic nucleus (AGN) Cygnus A using HAWC+ onboard SOFIA. We measure a highly polarized core of $11\pm3$% and $9\pm2$% with a position angle (P.A.) of polarization of $43\pm8^{\circ}$ and $39\pm7^{\circ}$ at 53 and 89 $\mu$m, respectively. We find (1) a synchrotron dominated core with a flat spectrum ($+0.21\pm0.05$) and a turn-over at $543\pm120$ $\mu$m, which implies synchrotron emission is insignificant in the infrared (IR), and (2) a $2-500$ $\mu$m bump peaking at $\sim40$ $\mu$m described by a blackbody component with color temperature of $107\pm9$ K. The polarized SED has the same shape as the IR bump of the total flux SED. We observe a change in the P.A. of polarization of $\sim20^{\circ}$ from 2 to 89 $\mu$m, which suggests a change of polarization mechanisms. The ultraviolet, optical and near-IR polarization has been convincingly attributed to scattering by polar dust, consistent with the usual torus scenario, though this scattered component can only be directly observed from the core in the near-IR. By contrast, the gradual rotation by $\sim20^{\circ}$ towards the far-IR, and the near-perfect match between the total and polarized IR bumps, indicate that dust emission from aligned dust grains becomes dominant at $10-100$ $\mu$m, with a large polarization of 10% at a nearly constant P.A. This result suggests that a coherent dusty and magnetic field structure dominates the $10-100$ $\mu$m emission around the AGN.