Quasar Main Sequence unfolded by 2.5D FRADO (Natural expression of Eddington ratio, black hole mass, and inclination)

Abstract

The quasar main sequence (QMS), characterized by the Eigenvector 1 (EV1), serves as a unifying framework for classifying type-1 active galactic nuclei (AGNs) based on their diverse spectral properties. Although a fully self-consistent physical interpretation has long been lacking, our physically motivated 2.5D FRADO (Failed Radiatively Accelerated Dusty Outflow) model naturally predicts that the Eddington ratio (m) is the primary physical driver of the QMS, with black hole mass (M BH) and inclination (i) acting as secondary contributors. We employed a dense grid of FRADO simulations of the geometry and dynamics of the broad-line region (BLR), covering a representative range of M BH and m. For each simulation, we computed the full width at half maximum (FWHM) of the Hβ line under different i. The resulting FWHM--m diagram closely resembles the characteristic trend observed in the EV1 parameter space. This establishes the role of m as the true proxy for the Fe II strength parameter (R Fe), and vice versa. Our results suggest that m can be regarded as the sole underlying physical tracer of R Fe and should therefore scale directly with it. The M BH accounts for the virial mass-related scatter in FWHM, while i acts as a secondary driver modulating R Fe and FWHM for a given m and M BH.

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