The X-ray Energy Dependence of the Relation between Optical and X-ray Emission in Quasars

Abstract

We develop a new approach to the well-studied anti-correlation between the optical-to-X-ray spectral index, alphaox, and the monochromatic optical luminosity, lopt. By cross-correlating the SDSS DR5 quasar catalog with the XMM-Newton archive, we create a sample of 327 quasars with X-ray S/N > 6, where both optical and X-ray spectra are available. This allows alphaox to be defined at arbitrary frequencies, rather than the standard 2500 Angstroms and 2 keV. We find that while the choice of optical wavelength does not strongly influence the alphaox-lopt relation, the slope of the relation does depend on the choice of X-ray energy. The slope of the relation becomes steeper when alphaox is defined at low (~ 1 keV) X-ray energies. This change is significant when compared to the slope predicted by a decrease in the baseline over which alphaox is defined. The slopes are also marginally flatter than predicted at high (~ 10 keV) X-ray energies. Partial correlation tests show that while the primary driver of alphaox is lopt, the Eddington ratio correlates strongly with alphaox when lopt is taken into account, so accretion rate may help explain these results. We combine the alphaox-lopt and Gamma -Lbol/LEdd relations to naturally explain two results: 1) the existence of the Gamma-lx relation as reported in Young et al. (2009) and 2) the lack of a Gamma-lopt relation. The consistency of the optical/X-ray correlations establishes a more complete framework for understanding the relation between quasar emission mechanisms. We also discuss two correlations with the hard X-ray bolometric correction, which we show correlates with both alphaox and Eddington ratio. This confirms that an increase in accretion rate correlates with a decrease in the fraction of up-scattered disk photons.