The Millimeter/X-ray Relation in Rapidly Accreting Supermassive Black Holes at z < 0.16

Abstract

A tight correlation between nuclear millimeter and X-ray emission has recently been found in nearby (z < 0.01) and low-Eddington ratio ( λEdd < 0.1) radio-quiet Active Galactic Nuclei (AGN), suggesting a common origin in the hot X-ray corona. We test this relation in nine more distant RQ AGN (z 0.06-0.16) with higher bolometric luminosities ((L bol/erg\,s-1)=45.3-46.3), Eddington ratios ( λEdd = 0.19-0.85), and X-ray bolometric corrections (κ2-10=29-194), selected from the Burst Alert Telescope (BAT) survey. We obtained quasi-simultaneous observations with Swift at 2-10 keV and the Atacama Large Millimeter/submillimeter Array (ALMA) at 100 GHz and with high angular resolution (<0.14&#34;). We find that these high-luminosity AGN lie above the millimeter/X-ray correlation defined by lower-luminosity sources. A joint fit to both samples yields a second-degree polynomial with an intrinsic scatter of 0.32 dex. Furthermore, the millimeter emission correlates linearly with both the UV disk luminosity and L bol, with intrinsic scatters of 0.45 and 0.35 dex, respectively. We propose that the deviation from the linear millimeter/X-ray relation arises from a two-component coronal electron population: thermal electrons that produce X-rays, but become less efficient at higher luminosities, and nonthermal electrons that produce millimeter emission and remain tied to L bol. Additional millimeter emission from outflow-driven shocks may also contribute, though spectral energy distribution modeling and spectral index studies favor a coronal origin.