The Photoionized Accretion Disk in Her X-1

TL;DR

This study analyzes high-resolution Chandra observations of Her X-1 to characterize the photoionized emission, absorption variability, and disk corona properties across different orbital and super-orbital phases.

Contribution

It provides detailed modeling of the photoionized emission and absorption in Her X-1, revealing phase-dependent variations and the presence of dense, cool material throughout the accretion disk.

Findings

Absorption columns vary significantly, causing most variability.

Dense, cool material is present throughout the disk, indicated by Fe K fluorescence.

Disk corona properties are consistent across phases, with some high-energy lines exceeding static model expectations.

Abstract

We present an analysis of several high-resolution Chandra grating observations of the X-ray binary pulsar Her X-1. With a total exposure of 170 ks, the observations are separated by years and cover three combinations of orbital and super-orbital phases. Our goal is to determine distinct properties of the photoionized emission and its dependence on phase-dependent variations of the continuum. We find that the continua can be described by a partial covering model which above 2 keV is consistent with recent results from \rxte studies and at low energies is consistent with recent \xmm and \sax studies. Besides a powerlaw with fixed index, an additional thermal blackbody of 114 eV is required to fit wavelengths above 12 \AA ($\sim$ 1 keV). We find that likely all the variability is caused by highly variable absorption columns in the range (1 -- 3)$\times 10^{23}$ cm$^{-2}$. Strong Fe K line fluorescence in almost all observations reveals that dense, cool material is present not only in the outer regions of the disk but interspersed throughout the disk. Most spectra show strong line emission stemming from a photoionized accretion disk corona. We model the line emission with generic thermal plasma models as well as with the photoionization code XSTAR and investigate changes of the ionization balance with orbital and superorbital phases. Most accretion disk coronal properties such as disk radii, temperatures, and plasma densities are consistent with previous findings for the low state. We find that these properties change negligibly with respect to orbital and super-orbital phases. A couple of the higher energy lines exhibit emissivities that are significantly in excess of expectations from a static accretion disk corona.