Does the mid-infrared-hard X-ray luminosity relation for active galactic nuclei depend on Eddington ratio?

Abstract

We revisit the correlation between the mid-infrared (6 μm) and hard X-ray (2--10 keV) luminosities of active galactic nuclei (AGNs) to understand the physics behind it. We construct an X-ray flux-limited sample of 571 type 1 AGNs with f0.5-2.0 \, keV > 2.4 × 10-12 erg cm-2 s-1, drawn from the ROSAT Bright Survey catalog. Cross-matching the sample with infrared data taken from Wide-field Infrared Survey Explorer, we investigate the relation between the rest-frame 6 μm luminosity (L 6) and the rest-frame 2--10 keV luminosity (L X), where L 6 is corrected for the contamination of host galaxies by using the spectral energy distribution fitting technique. We confirm that L 6 and L X are correlated over four orders of magnitude, in the range of L X = 1042-46 erg s-1. We investigate what kinds of physical parameters regulate this correlation. We find that L X/L 6 clearly depends on the Eddington ratio (λ Edd) as λ Edd = -(0.56 0.10) \, (L X/L 6) - (1.07 0.05), even taking into account quasars that are undetected by ROSAT as well as those detected by XMM-Newton in the literature. We also add hyper-luminous quasars with L 6 > 1046 erg s-1 in the literature and perform a correlation analysis. The resultant correlation coefficient is -0.41 0.07, indicating a moderately tight correlation between L X/L 6 and λ Edd. This means that AGNs with high Eddington ratios tend to have lower X-ray luminosities with respect to the mid-infrared luminosities. This dependence can be interpreted as a change in the structure of the accretion flow.