Millimeter VLBI constraints on the central magnetic field and symmetric jet production in the twin-jet galaxy NGC 1052

TL;DR

This study uses millimeter VLBI observations to analyze the symmetry, magnetic fields, and absorption effects in the jets of galaxy NGC 1052, revealing intrinsic jet symmetry and the influence of free-free absorption.

Contribution

First high-frequency spectral index imaging of NGC 1052, constraining magnetic field configuration and demonstrating jet symmetry at 86 GHz.

Findings

Jets are intrinsically symmetric at launch.

Free-free absorption causes asymmetry at 43 GHz.

Jet width supports a parabolic profile on small scales.

Abstract

This paper investigates the symmetry and magnetic field properties of the jets in the radio galaxy NGC 1052, with particular attention to the impact of the ionized torus that surrounds the central region on the emitted radiation. Our study is based on three new 43 GHz Very-Long-Baseline Interferometry (VLBI) observations and one 86 GHz observation conducted between April 2021 and April 2022. We derive key jet parameters, such as speed, width, and flux density for both jets at the two frequencies and compare them with those obtained from previous VLBI campaigns. Additionally, we present the first (43-86) GHz spectral index image of NGC 1052, which is crucial to assess the role of the torus at high frequencies. Finally, we leverage the derived observational parameters to constrain the magnetic field strength and configuration in the launched jets. We observe variability in the jet morphology at 43 GHz across the three epochs, which can be associated with the propagation of jet knots launched from the nuclear region. The stacked 43 GHz image reveals that the western and receding jet is approximately three times fainter than its eastern (approaching) counterpart in the sub-mas region. This asymmetry, together with the (43-86) GHz spectral index map, suggests that free-free absorption may affect the 43 GHz emission. On the contrary, the jets appear highly symmetric at 86 GHz. From the stacked images at 43 GHz and 86 GHz, we extract the jet width, which is consistent with previous VLBI studies and supports the presence of a parabolic jet profile on very compact scales. Overall, our results suggest that the jets are intrinsically launched symmetrically, and that the observed time-dependent asymmetries may result from free-free absorption by the torus and the downstream propagation of jet components, a scenario supported by previous theoretical studies.