A characterization of the NGC 4051 soft X-ray spectrum as observed by XMM-Newton

TL;DR

This study analyzes the high-resolution soft X-ray spectrum of NGC 4051 during a low flux state, revealing a complex, multi-phase photoionized plasma with specific ionization and column density properties, using XMM-Newton data and photoionization modeling.

Contribution

First detailed characterization of NGC 4051's soft X-ray spectrum during a low flux state using high-resolution spectroscopy and photoionization modeling.

Findings

Spectrum dominated by emission from photoionized plasma

Multiple ionization phases are required to fit the spectrum

Warm absorber is present with specific ionization and density parameters

Abstract

Soft X-rays high resolution spectroscopy of obscured AGNs shows the existence of a complex soft $X$-ray spectrum dominated by emission lines of He and H-like transitions of elements from Carbon to Neon, as well as L-shell transitions due to iron ions. In this paper we characterize the XMM-Newton RGS spectrum of the Seyfert 1 galaxy NGC 4051 observed during a low flux state and infer the physical properties of the emitting and absorbing gas in the soft X-ray regime. X-ray high-resolution spectroscopy offers a powerful diagnostic tool since the observed spectral features strongly depend on the physical properties of matter (ionization parameter U, electron density n_e, hydrogen column density N_H), which in turn are tightly related to the location and size of the X-ray emitting clouds. We carried out a phenomenological study to identify the atomic transitions detected in the spectra. This study suggests that the spectrum is dominated by emission from a photoionised plasma. Then, we used the photoionization code Cloudy to produce synthetic models for the emission line component and the warm absorber observed during phases of high intrinsic luminosity. The low state spectrum cannot be described by a single photoionization component. A multi-ionization phase gas with ionization parameter in the range log U = 0.63-1.90 and column density log N_H = 22.10-22.72 cm^-2 is required, while the electron density n_e remains unconstrained. A warm absorber medium is required by the fit with parameters log U = 0.85, log N_H = 23.40 and log n_e \ut< 5. The model is consistent with an X-ray emitting regions at a distance > 5 x 10^-2 pc from the central engine.