Accretion Geometry of the Low-Mass X-ray Binary Aquila X-1 in the Soft and Hard States

TL;DR

This study analyzes Suzaku X-ray observations of Aquila X-1 during different states, revealing changes in accretion geometry from a disk to a hot flow, with detailed spectral modeling across a broad energy range.

Contribution

It provides the first detailed spectral analysis of Aquila X-1 across soft and hard states over a wide energy band, constraining the accretion flow geometry and state-dependent spectral components.

Findings

In soft state, spectrum fits an optically-thick disk plus Comptonized blackbody.

In hard state, spectrum indicates a truncated disk at ~21 km and a hot inner flow.

Spectral parameters vary significantly between states, reflecting different accretion geometries.

Abstract

The neutron-star Low-Mass X-ray Binary Aquila X-1 was observed seven times in total with the Suzaku X-ray observatory from September 28 to October 30 in 2007, in the decaying phase of an outburst. In order to constrain the flux-dependent accretion geometry of this source over wider energy bands than employed in most of previous works, the present study utilized two out of the seven data sets. The 0.8-31 keV spectrum on September 28, taken with the XIS and HXD-PIN for an exposure of 13.8 ks, shows an absorbed 0.8-31 keV flux of $3.6\times 10^{-9}$ erg s$^{-1}$ cm$^{-2}$, together with typical characteristics of the soft state of this type of objects. The spectrum was successfully explained by an optically-thick disk emission plus a Comptonized blackbody component. Although these results are in general agreement with previous studies, the significance of a hard tail recently reported using the same data was inconclusive in our analysis. The spectrum acquired on October 9 for an exposure of 19.7 ks was detected over a 0.8-100 keV band with the XIS, HXD-PIN, and HXD-GSO, at an absorbed flux of $8.5\times 10^{-10}$ erg s$^{-1}$ cm$^{-2}$ (in 0.8-100 keV). It shows characteristics of the hard state, and was successfully explained by the same two continuum components but with rather different parameters including much stronger thermal Comptonization, of which the seed photon source was identified with blackbody emission from the neutron-star surface. As a result, the accretion flow in the hard state is inferred to take a form of an optically-thick and geometrically-thin disk down to a radius of $21\pm 4$ km from the neutron star, and then turn into an optically-thin nearly-spherical hot flow.