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Magnetic field strength of a neutron-star-powered ultraluminous X-ray source

Authors :
Brightman, Murray
Harrison, Fiona A.
Fuerst, Felix
Middleton, Matthew J.
Walton, Dominic J.
Stern, Daniel
Fabian, Andrew C.
Heida, Marianne
Barret, Didier
Bachetti, Matteo
Publication Year :
2018

Abstract

Ultraluminous X-ray sources (ULXs) are bright X-ray sources in nearby galaxies not associated with the central supermassive black hole. Their luminosities imply they are powered by either an extreme accretion rate onto a compact stellar remnant, or an intermediate mass ($\sim100-10^5$ M$_{\odot}$) black hole. The recent detection of coherent pulsations coming from three bright ULXs demonstrates that some of these sources are powered by accretion onto a neutron star, implying accretion rates significantly in excess of the Eddington limit, a high degree of geometric beaming, or both. The physical challenges associated with the high implied accretion rates can be mitigated if the neutron star surface field is high - in the magnetar regime ($10^{14}$ G), since this suppresses the electron scattering cross section, reducing the radiation pressure that chokes off accretion for high luminosities. One of the few ways to determine surface magnetic fields is through the detection of cyclotron resonance scattering features (CRSFs) produced by the transition of charged particles between quantized Landau levels. To date, CRSFs have only been detected in Galactic accreting pulsars. Here we present the detection at 3.8-{\sigma} significance of a strong absorption line at a rest-frame energy of 4.5 keV in the Chandra spectrum of a ULX in M51. We find that this feature is likely to be a CRSF produced by the strong magnetic field of a neutron star. Assuming scattering off electrons, the magnetic field strength is implied to be $\sim10^{11}$ G, however the line is narrower than any electron CRSFs previously observed, and assuming thermal broadening, the implied temperature is significantly cooler than the accretion disk or column. The line shape is, however, consistent with a proton resonance scattering feature, implying that the neutron star has a magnetic field near the surface of B$\sim10^{15}$ G.<br />Comment: Author version of the paper published in Nature Astronomy on 26 February 2018. See free-to-view published version here: http://rdcu.be/HQpR

Details

Database :
arXiv
Publication Type :
Report
Accession number :
edsarx.1803.02376
Document Type :
Working Paper
Full Text :
https://doi.org/10.1038/s41550-018-0391-6