# The X-ray and Mid-Infrared luminosities in Luminous Type 1 Quasars

**Authors:** Chien-Ting J. Chen (PSU, Dartmouth), Ryan C. Hickox, Andrew D., Goulding, Daniel Stern, Roberto Assef, Christopher S. Kochanek, Michael J. I., Brown, Chris M. Harrison, Kevin N. Hainline, Stacey Alberts, David M., Alexander, Mark Brodwin, Agnese Del Moro, William R. Forman, Varoujan, Gorjian, Christine Jones, Stephen S. Murray, Alexandra Pope, and Emmanouel, Rovilos

arXiv: 1701.05207 · 2017-08-22

## TL;DR

This study analyzes a large sample of luminous type 1 quasars to clarify the intrinsic relationship between X-ray and mid-infrared luminosities, revealing a luminosity-dependent bilinear correlation that differs from local Seyfert galaxies.

## Contribution

It demonstrates that observational biases, especially X-ray flux limits, significantly affect the observed $L_{X}-L_{MIR}$ relations and establishes a bilinear relation for luminous quasars.

## Key findings

- The $L_{X}-L_{MIR}$ relation is bilinear with a shallower slope at higher luminosities.
- X-ray flux limits are the primary factor causing discrepancies in previous studies.
- Luminous quasars have a non-linear, luminosity-dependent $L_{X}-L_{MIR}$ relation.

## Abstract

Several recent studies have reported different intrinsic correlations between the AGN mid-IR luminosity ($L_{MIR}$) and the rest-frame 2-10 keV luminosity ($L_{X}$) for luminous quasars. To understand the origin of the difference in the observed $L_{X}-L_{MIR}$ relations, we study a sample of 3,247 spectroscopically confirmed type 1 AGNs collected from Bo\"{o}tes, XMM-COSMOS, XMM-XXL-North, and the SDSS quasars in the Swift/XRT footprint spanning over four orders of magnitude in luminosity. We carefully examine how different observational constraints impact the observed $L_{X}-L_{MIR}$ relations, including the inclusion of X-ray non-detected objects, possible X-ray absorption in type 1 AGNs, X-ray flux limits, and star formation contamination. We find that the primary factor driving the different $L_{X}-L_{MIR}$ relations reported in the literature is the X-ray flux limits for different studies. When taking these effects into account, we find that the X-ray luminosity and mid-IR luminosity (measured at rest-frame $6\mu m$, or $L_{6\mu m}$) of our sample of type 1 AGNs follow a bilinear relation in the log-log plane: $\log L_X =(0.84\pm0.03)\times\log L_{6\mu m}/10^{45}{\rm erg\;s^{-1}} + (44.60\pm0.01)$ for $L_{6\mu m} < 10^{44.79}{\rm erg\;s^{-1}} $, and $\log L_X = (0.40\pm0.03)\times\log L_{6\mu m}/10^{45}{\rm erg\;s^{-1}} +(44.51\pm0.01)$ for $L_{6\mu m} \geq 10^{44.79}{\rm erg\;s^{-1}} $. This suggests that the luminous type 1 quasars have a shallower $L_{X}-L_{MIR}$ correlation than the approximately linear relations found in local Seyfert galaxies. This result is consistent with previous studies reporting a luminosity-dependent $L_{X}-L_{MIR}$ relation, and implies that assuming a linear $L_{X}-L_{MIR}$ relation to infer the neutral gas column density for X-ray absorption might overestimate the column densities in luminous quasars.

## Full text

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## Figures

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## References

86 references — full list in the complete paper: https://tomesphere.com/paper/1701.05207/full.md

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Source: https://tomesphere.com/paper/1701.05207