# Swift observations of SMC X-3 during its 2016-2017 super-Eddington   outburst

**Authors:** Shan-Shan Weng, Ming-Yu Ge, Hai-Hui Zhao, Wei Wang, Shuang-Nan Zhang,, Wei-Hao Bian, Qi-Rong Yuan

arXiv: 1701.02983 · 2017-07-19

## TL;DR

This study monitored the 2016-2017 super-Eddington outburst of SMC X-3 with Swift, revealing its extreme luminosity, magnetic field, and pulse profile evolution, providing insights into neutron star accretion physics.

## Contribution

First detailed analysis of SMC X-3's super-Eddington outburst with Swift, measuring orbital parameters, magnetic field, and spectral components during extreme luminosity.

## Key findings

- X-ray luminosity reached ~10^39 erg/s during outburst
- Spin frequency increased and approached equilibrium, indicating a strong magnetic field
- Emergence of a low-temperature thermal component as flux decayed

## Abstract

The Be X-ray pulsar, SMC X-3 underwent a giant outburst from 2016 August to 2017 March, which was monitored with the Swift satellite. During the outburst, its broadband flux increased dramatically, and the unabsorbed X-ray luminosity reached an extreme value of $\sim 10^{39}$ erg/s around August 24. Using the Swift/XRT data, we measure the observed pulse frequency of the neutron star to compute the orbital parameters of the binary system. After applying the orbital corrections to Swift observations, we find that the spin frequency increases steadily from 128.02 mHz on August 10 and approach to spin equilibrium $\sim 128.74$ mHz in 2017 January with an unabsorbed luminosity of $L_{\rm X} \sim 2\times10^{37}$ erg/s, indicating a strong dipolar magnetic field $B \sim 6.8\times10^{12}$ G at the neutron star surface. The spin-up rate is tightly correlated with its X-ray luminosity during the super-Eddington outburst. The pulse profile in the Swift/XRT data is variable, showing double peaks at the early stage of outburst and then merging into a single peak at low luminosity. Additionally, we report that a low temperature ($kT \sim 0.2$ keV) thermal component emerges in the phase-averaged spectra as the flux decays, and it may be produced from the outer truncated disk or the boundary layer between the exterior flow and the magnetosphere.

## Full text

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## Figures

2 figures with captions in the complete paper: https://tomesphere.com/paper/1701.02983/full.md

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Source: https://tomesphere.com/paper/1701.02983