Probing the Physical Origin of the Balmer Decrement in the Broad-line Region of Nearby Active Galactic Nuclei via Spectral Variability

TL;DR

This study investigates the physical origins of the Balmer decrement in AGNs by analyzing spectral variability, revealing that luminosity changes and radiative transfer effects significantly influence the Balmer decrement, rather than dust reddening.

Contribution

It provides new insights into the physical mechanisms affecting the Balmer decrement in AGNs, emphasizing the roles of luminosity variation and radiative transfer effects over dust reddening.

Findings

Balmer decrement correlates inversely with Eddington ratio.

Temporal Balmer decrement variation strongly anti-correlates with AGN luminosity.

Radiative transfer effects are key to understanding Balmer decrement variability.

Abstract

To investigate the physical origin of the Balmer decrement in the broad-line region of active galactic nuclei (AGNs), we measure the temporal variability of the fluxes of the broad H$\beta$ and H$\alpha$ emission lines using multi-epoch spectroscopic data of low-redshift AGNs from the Sloan Digital Sky Survey. The analysis of the mean spectra reveals that the Balmer decrement shows no correlation with AGN luminosity, while it is inversely correlated with the Eddington ratio. However, the temporal variation of the Balmer decrement in individual objects exhibits an even stronger anti-correlation with AGN luminosity, suggesting that the change in AGN luminosity plays a dominant role in determining the Balmer decrement. By comparing the temporal evolution of the Balmer decrement with the continuum color, we find that reddening due to the AGN itself may not be the primary factor. Instead, radiative transfer effects and excitation mechanisms, which deviate from the Case B recombination, appear to be critical for the variation of the Balmer decrement. These results provide useful insights into the underlying physics of changing-look AGNs and high-$z$ AGNs, such as the ``little red dots'', which exhibit extreme values of the Balmer decrement that can be misinterpreted as evidence for dust.