The role of the Gamma-Eddington ratio relation on the X-ray Baldwin effect in Active Galactic Nuclei

Abstract

The X-ray Baldwin effect is the inverse correlation between the equivalent width (EW) of the narrow component of the iron Kalpha line and the X-ray luminosity of active galactic nuclei (AGN). A similar trend has also been observed between Fe Kalpha EW and the Eddington ratio (lambdaEdd). Using Chandra/HEG results of Shu et al. (2010) and bolometric corrections we study the relation between EW and the lambdaEdd, and find that log EW = (-0.13+/-0.03)log(lambdaEdd) + 1.47. We explore the role of the known positive correlation between the photon index of the primary X-ray continuum (Gamma) and lambdaEdd on the X-ray Baldwin effect. We simulate the iron Kalpha line emitted by populations of unabsorbed AGN considering 3 different geometries of the reflecting material: toroidal, spherical-toroidal and slab. We find that the Gamma-lambdaEdd correlation cannot account for the whole X-ray Baldwin effect, unless a strong dependence of Gamma on lambdaEdd, such as the one recently found by Risaliti et al. (2009) and Jin et al. (2012), is assumed. No clear correlation is found between EW and Gamma. We conclude that a good understanding of the slope of the Gamma-lambdaEdd relation is critical to assess whether the trend plays a leading or rather a marginal role in the X-ray Baldwin effect.