A cooling neutron star crust after recurrent outbursts: modelling the accretion outburst history of Aql X-1

Abstract With our neutron star crust cooling code nscool, we track the thermal evolution of the neutron star in Aql X-1 over the full accretion outburst history from 1996 until 2015. For the first time, we model many outbursts (23 outbursts were detected) collectively and in great detail. This allow...

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Bibliographic Details
Published in:Monthly notices of the Royal Astronomical Society 2018-07, Vol.477 (3), p.2900-2916
Main Authors: Ootes, Laura S, Wijnands, Rudy, Page, Dany, Degenaar, Nathalie
Format: Article
Language:English
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Summary:Abstract With our neutron star crust cooling code nscool, we track the thermal evolution of the neutron star in Aql X-1 over the full accretion outburst history from 1996 until 2015. For the first time, we model many outbursts (23 outbursts were detected) collectively and in great detail. This allows us to investigate the influence of previous outbursts on the internal temperature evolution and to test different neutron star crust cooling scenarios. Aql X-1 is an ideal test source for this purpose, because it shows frequent, short outbursts and thermally dominated quiescence spectra. The source goes into outburst roughly once a year for a few months. Assuming that the quiescent Swift/X-Ray Telescope observations of Aql X-1 can be explained within the crust cooling scenario, we find three main conclusions. First, the data are well reproduced by our model if the envelope composition and shallow heating parameters are allowed to change between outbursts. This is not the case if both shallow heating parameters (strength and depth) are tied throughout all accretion episodes, supporting earlier results that the properties of the shallow heating mechanism are not constant between outbursts. Secondly, from our models, shallow heating could not be connected to one specific spectral state during outburst. Thirdly, and most importantly, we find that the neutron star in Aql X-1 does not have enough time between outbursts to cool down to crust–core equilibrium and that heating during one outburst influences the cooling curves of the next.
ISSN:0035-8711
1365-2966
DOI:10.1093/mnras/sty825