Changing-state active galactic nuclei (CSAGNs) exhibit rapid variability; their mass accretion rates can change by several orders of magnitude in a few years. This provides us with a unique opportunity to study the evolution of the inner accretion flow almost in real time. Here we used over 1, 000 observations to study the broadband X‐ray spectra of a sample of five CSAGNs, spanning three orders of magnitude in Eddington ratio (λ_̊m Edd), using phenomenological models to trace the evolution of key spectral components. We derive several fundamental parameters, such as the photon index, soft excess strength, reflection strength, and luminosities of the soft excess and primary continuum. We find that the soft excess and primary continuum emissions show a very strong positive correlation (p ≪ 10^ -10), suggesting a common physical origin. The soft excess strength does not show any dependence on the reflection parameter, suggesting that in these objects the soft excess is not dominated by a blurred ionized reflection process. On the other hand, the strength of the soft excess is found to be strongly positively correlated with the Eddington ratio (p ≪ 10^ -10), and we find that the soft excess vanishes below łog λ_ ̊m Edd ∼ -2. 5. Moreover, we find a clear V-shaped relation for Γ-λ_̊m Edd, with a break at łog λ_ ̊m Edd =-2. 47 Our findings indicate a change in the geometry of the inner accretion flow at low Eddington ratios, and that the soft excess is primarily produced via warm Comptonization.
Jana et al. (Mon,) studied this question.