The Broadband Spectral Variability of Holmberg IX X-1

TL;DR

This study presents broadband X-ray observations of Holmberg IX X-1, revealing spectral variability characterized by thermal components and a steep powerlaw tail, with flux variations suggesting a face-on funnel-like accretion geometry.

Contribution

First comprehensive broadband spectral variability analysis of Holmberg IX X-1 across six epochs, including new low-flux observations and constraints on ultra-fast outflows.

Findings

0.3-10 keV flux varies by factor of ~3

15-40 keV flux varies by only ~20%

Iron absorption features from ultra-fast outflows are absent

Abstract

We present results from four new broadband X-ray observations of the extreme ultraluminous X-ray source Holmberg IX X-1 ($L_{\rm{X}} > 10^{40}$ erg/s), performed by $Suzaku$ and $NuSTAR$ in coordination. Combined with the archival data, we now have broadband observations of this remarkable source from six separate epochs. Two of these new observations probe lower fluxes than seen previously, allowing us to extend our knowledge of the broadband spectral variability exhibited. The spectra are well fit by two thermal blackbody components, which dominate the emission below 10 keV, as well as a steep ($\Gamma \sim 3.5$) powerlaw tail which dominates above $\sim$15 keV. Remarkably, while the 0.3-10.0 keV flux varies by a factor of $\sim$3 between all these epochs, the 15-40 keV flux varies by only $\sim$20%. Although the spectral variability is strongest in the $\sim$1-10 keV band, both of the thermal components are required to vary when all epochs are considered. We also re-visit the search for iron absorption features, leveraging the high-energy $NuSTAR$ data to improve our sensitivity to extreme velocity outflows in light of the ultra-fast outflow recently detected in NGC 1313 X-1. Iron absorption from a similar outflow along our line of sight can be ruled out in this case. We discuss these results in the context of super-Eddington accretion models that invoke a funnel-like geometry for the inner flow, and propose a scenario in which we have an almost face-on view of a funnel that expands to larger radii with increasing flux, resulting in an increasing degree of geometrical collimation for the emission from intermediate temperature regions.