Constraining distance and inclination angle of V4641 Sgr using ${\it SWIFT}$ and ${\it NuSTAR}$ observations during low soft spectral state

TL;DR

This study uses joint NuSTAR and Swift observations to precisely measure the distance, inclination, and inner disk radius of V4641 Sgr during different spectral states, revealing unique features like potential nickel emission lines.

Contribution

First detailed constraints on V4641 Sgr's geometry during a soft state using relativistic spectral modeling and MCMC techniques, including potential detection of nickel emission lines.

Findings

Inner disk radius constrained to ~2.43 Rg

Inclination angle estimated at ~69.5 degrees

Distance to source approximately 10.8 kpc

Abstract

We present results from ${\it NuSTAR}$ and ${\it SWIFT}$/XRT joint spectral analysis of V4641 Sgr during a disk dominated or soft state as well as a powerlaw dominated or hard state. The soft state spectrum is well modeled by a relativistically blurred disk emission, a powerlaw, a broad Iron line, two narrow emission lines and two edges. The Markov Chain Monte Carlo simulation technique and the relativistic effects seen in the disk and broad Iron line allow us to self-consistently constrain the inner disk radius, disk inclination angle and distance to the source at 2.43$^{+0.39}_{-0.17}$ R$_g$ (GM/c$^2$), 69.5$^{+12.8}_{-4.2}$ degrees and 10.8$^{+1.6}_{-2.5}$ kpc respectively. For the hard state, the spectrum is a power-law with a weakly broad Iron line and an edge. The distance estimate gives a measure of the Eddington fraction, $L_{2.0 - 80.0 keV}/L_{Edd}$, to be $\sim$1.3 $\times$ 10$^{-2}$ and $\sim$1.9 $\times$ 10$^{-3}$ for the soft and hard states respectively. Unlike many other typical black hole systems which are always in a hard state at such low Eddington fraction, V4641 Sgr shows a soft, disk dominated state. The soft state spectrum shows narrow emission lines at $\sim 6.95$ and $\sim 8.31$ keV which can be identified as being due to emission from highly ionized Iron and Nickel in an X$-$ray irradiated wind respectively. If not due to instrumental effect or calibration error, this would be the first detection of a Ni fluorescent line in a black hole X$-$ray binary.