The multi-epoch X-ray tale of I Zwicky 1 outflows

TL;DR

This study analyzes long-term X-ray observations of I Zwicky 1, revealing complex, variable warm absorber ionization states driven by gas density and detecting an ultra-fast wind, enhancing understanding of AGN outflows.

Contribution

It provides new insights into the variability and driving mechanisms of warm absorbers and ultra-fast winds in I Zwicky 1 through multi-epoch X-ray analysis.

Findings

Warm absorber ionization states vary unpredictably over time.

Ionization driven by gas density rather than luminosity.

Detection of an ultra-fast wind at 0.26c velocity.

Abstract

The narrow-line Seyfert 1 galaxy I Zwicky 1 shows a unique and complex system of ionised gas in outflow, which consists of an ultra-fast wind and a two-component warm absorber. In the last two decades, XMM-Newton monitored the source multiple times enabling the study of the long-term variability of the various outflows. Plasma in photoionisation equilibrium with the ionising source responds and varies accordingly to any change of the ionising luminosity. However, detailed modelling of the past RGS data has shown no correlation between the plasma ionisation state and the ionising continuum, revealing a complex long-term variability of the multi-phase warm absorber. Here, we present a new observation of I Zwicky 1 by XMM-Newton taken in early 2020 characterised by a lower X-ray flux state. The soft X-ray spectrum from the RGS reveals the two components of the warm absorber with $\log \xi \sim -1.0$ and $\log \xi \sim 1.7$. Comparing our results with the previous observations, the ionisation state of the two absorbing gas components is continuously changing, following the same unpredictable behaviour. The new results strengthen the scenario in which the ionisation state of the warm absorber is driven by the density of the gas rather than the ionising luminosity. In particular, the presence of a radiation driven, inhomogeneous clumpy outflow may explain both the variability in ionisation throughout the years and the line-locked N V system observed in the UV band. Finally, the EPIC-pn spectrum reveals an ultra-fast wind with an outflow velocity of $\sim 0.26c$ and ionisation parameter of $\log \xi \sim 3.8$.