Testing Black Hole Jet Scaling Relations in Low Luminosity AGN

TL;DR

This study analyzes low-luminosity AGNs to identify reliable indicators of jet power, finding X-ray emission as a consistent estimator and revealing the origin of emissions from jets rather than obscuration effects.

Contribution

It demonstrates that X-ray emission reliably traces jet power in low-luminosity AGNs and clarifies the emission origins, expanding understanding of AGN jet activity at low luminosities.

Findings

X-ray emission is a reliable jet-power indicator.

Most sources are classified as Low-Excitation Galaxies.

X-ray and radio emissions originate from the jet base.

Abstract

We present the results of the analysis of a sample of 17 low-luminosity (L_x < 1e42 erg/s), radio loud AGNs in massive galaxies. The sample is extracted from the SDSS database and it spans uniformly a wide range in optical [OIII] emission line and radio luminosity, but within a narrow redshift range (0.05 < z < 0.11) and a narrow super massive black hole mass range (~ 1e8 M_sun). For these sources we measured core X-ray emission with the Chandra X-ray telescope and radio emission with the VLA. Our main goal is to establish which emission component, if any, can be regarded as the most reliable accretion/jet-power estimator at these regimes. In order to do so, we studied the correlation between emission line properties, radio luminosity, radio spectral slopes and X-ray luminosity, as well as more complex multi-variate relations involving black hole mass, such as the fundamental plane of black hole activity. We find that 15 out of 17 sources of our sample can be classified as Low-Excitation Galaxies (LEG) and their observed properties suggest X-ray and radio emission to originate from the jet basis. We also find that X-ray emission does not appear to be affected by nuclear obscuration and can be used as a reliable jet-power estimator. More generally, X-ray, radio and optical emission appear to be related, although no tight correlation is found. In accordance with a number of recent studies of this class of objects these findings may be explained by a lack of cold (molecular) gaseous structures in the innermost region of these massive galaxies.