The nature of X-ray spectral variability in SWIFT J2127.4+5654

TL;DR

This study analyzes X-ray spectral variability in Seyfert galaxy SWIFT J2127.4+5654 using flux-flux plots, revealing distinct variable and constant spectral components and demonstrating the method's effectiveness in disentangling complex spectral features.

Contribution

It introduces the application of flux-flux plots to separate variable and constant X-ray spectral components in Seyfert galaxies, enhancing spectral analysis techniques.

Findings

Variable continuum modeled as a power law with relativistic reflection.

Identification of a variable neutral absorber component.

Detection of constant blackbody and reflection components.

Abstract

We study the flux-flux plots (FFPs) of the Seyfert galaxy SWIFT J2127.4+5654 which was observed simultaneously by XMM-Newton and NuSTAR. The 0.7-2 keV FFPs show a non-linear behaviour, while they are well fitted by a straight line, in the $\sim 2-40$ keV range. Without any additional modelling, this result strongly suggests that neither absorption nor spectral slope variations can contribute significantly to the observed variability above 2 keV (on time scales $\lesssim$5 days, at least). The FFP method is capable of separating the variable and the constant X-ray spectral components in this source. We found that the low-, average- and high-flux spectra of the variable components are consistent with a power law varying in normalisation only plus a relativistic reflection component varying simultaneously with the continuum. At low energies, we identify an additional variable component, consistent with a neutral absorber with a variable covering fraction. We also detect two spectral components whose fluxes remain constant over the duration of the observations. These components can be well described by a blackbody emission of $kT_{\rm BB}\sim 0.18\, \rm keV$, dominating at soft X-rays, and a reflection component from neutral material. The spectral model resulting from the FFP analysis can fit well the energy spectra of the source. We suggest that a combined study of FFPs and energy spectra in the case of X-ray bright and variable Seyferts can identify, unambiguously, the various spectral components, and can lift the degeneracy that is often observed within different models fitting equally well time-averaged spectra of these objects.