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Low-power jet–interstellar medium interaction in NGC 7319 revealed by JWST/MIRI MRS

M. Pereira-Santaella, Javier Álvarez-Márquez, I. García-Bernete, Á. Labiano, L. Colina, A. Alonso‐Herrero, E. Bellocchi, S. García‐Burillo, S. F. Hönig, C. Ramos Almeida, D. J. Rosario

2022Astronomy and Astrophysics62 citationsDOIOpen Access PDF

Abstract

We present JWST/MIRI MRS spectroscopy of NGC 7319, the largest galaxy in the Stephan’s Quintet, observed as part of the Early Release Observations (ERO). NGC 7319 hosts a type 2 active galactic nucleus (AGN) and a low-power radio jet ( L 1.4 GHz = 3.3 × 10 22 W Hz −1 ) with two asymmetric radio hotspots at 430 pc (N2) and 1.5 kpc (S2) projected distances from the unresolved radio core. The MRS data suggest that the molecular material in the disk of the galaxy decelerates the jet and causes this length asymmetry. We find enhanced emission from warm and hot H 2 ( T w = 330 ± 40 K, T h = 900 ± 60 K) and ionized gas at the intersection between the jet axis and dust lanes in the disk. This emission is coincident with the radio hotspot N2, the hotspot closer to the core, suggesting that the jet–interstellar medium (ISM) interaction decelerates the jet. Conversely, the mid-infrared emission at the more distant hotspot is fainter, more highly ionized, and with lower H 2 excitation, suggesting a more diffuse atomic environment where the jet can progress to farther distances. At the N2 radio hotspot, the ionized gas mass ( M ion = (2.4–12)×10 5 M ⊙ ) is comparable to that of the warm H 2 , but the former is more turbulent ( σ ion ∼ 300 vs. σ H 2 ∼ 150 km s −1 ), so the mechanical energy of the ionized gas is ∼1.3–10 times higher. From these estimates, we find that only < 1% of the jet energy remains as mechanical energy in these two ISM phases at N2. We also find extended ( r > 0.3–1.5 kpc) high-ionization emission ([Mg V ], [Ne VI ], and [Ne V ]) close to the radio hotspots. This initial analysis of NGC 7319 shows the potential of MIRI/MRS to investigate the AGN feedback mechanisms due to radio jets and their radiation field in the, often heavily dust-enshrouded, central regions of galaxies. Understanding these mechanisms is an essential ingredient in the development of cosmological simulations of galaxy evolution.

Topics & Concepts

PhysicsAstrophysicsHotspot (geology)GalaxyInterstellar mediumIonizationRadio galaxyActive galactic nucleusPlasmaAstronomyIonGeophysicsQuantum mechanicsGalaxies: Formation, Evolution, PhenomenaAstrophysics and Star Formation StudiesAstrophysical Phenomena and Observations
Low-power jet–interstellar medium interaction in NGC 7319 revealed by JWST/MIRI MRS | Litcius