The low-luminosity behaviour of the 4U 0115+63 Be/X-ray transient

Escorial, A. Rouco; Nielsen, A.-S. Bak; Wijnands, Rudy; Cavecchi, Y.; Degenaar, N.; Patruno, A.

doi:10.1093/mnras/stx2111

Cited by 16 publications

(44 citation statements)

References 47 publications

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“…This indicates that if the emission mechanism is linked to the periastron passage, it is not always active. This is similar to what has been found for the mini type-I outbursts in 4U 0115+63 and V 0332+53 which are not always present at periastron passages(Wijnands & Degenaar 2016;Rouco Escorial et al 2017).…”

supporting

confidence: 90%

“…The purpose of our campaign was to determine if the crust of the NS in this system was significantly heated during this outburst and, if so, to follow its crust cooling behaviour. Such cooling of an accretion-heated crusts may have been observed for two other Be/X-ray transients (4U 0115+63 and V 0332+53) after the type-II outbursts they exhibited (Wijnands & Degenaar 2016;Rouco Escorial et al 2017). However, contrary to what was found for these two systems, we do not see any strong evidence of such crust heating and cooling behaviour in GRO J1750-27 and, consequently, we infer that the NS crust was not significantly heated during the previous outburst (see Section 3.1).…”

Section: Discussionsupporting

confidence: 56%

“…This model could also adequately describe our Chandra spectra, however, in the rest of our paper we mainly use the results obtained when using the power-law and blackbody models in order to be able to compare our source with the other two sources (4U 0115+63 and V 0332+53), for which similar studies have been performed. However, only blackbody and power-law fit results have reported for these two sources (see Wijnands & Degenaar 2016;Rouco Escorial et al 2017). Nevertheless, for completeness, we list our NSA model results in Appendix B.…”

Section: Chandra Spectral Analysismentioning

confidence: 99%

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Quiescent X-ray variability in the neutron star Be/X-ray transient GRO J1750−27

Escorial

Wijnands

Ootes

et al. 2019

A&A

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The Be/X-ray transient GRO J1750-27 exhibited a type-II (giant) outburst in 2015. After the source transited to quiescence, we triggered our multi-year Chandra monitoring programme to study its quiescent behaviour. The programme was designed to follow the cooling of a potentially heated neutron-star crust due to accretion of matter during the preceding outburst, similar to what we potentially have observed before in two other Be/X-ray transients, namely 4U 0115+63 and V 0332+53. However, unlike for these other two systems, we do not find any strong evidence that the neutron-star crust in GRO J1750-27 was indeed heated during the accretion phase. We detected the source at a rather low X-ray luminosity (∼10 33 erg s −1 ) during only three of our five observations. When the source was not detected it had very low-luminosity upper limits (< 10 32 erg s −1 ; depending on assumed spectral model). We interpret these detections and the variability observed as emission likely due to very low-level accretion onto the neutron star. We also discuss why the neutron-star crust in GRO J1750-27 might not have been heated while the ones in 4U 0115+63 and V 0332+53 possibly were.

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supporting

confidence: 90%

Section: Discussionsupporting

confidence: 56%

Section: Chandra Spectral Analysismentioning

confidence: 99%

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Quiescent X-ray variability in the neutron star Be/X-ray transient GRO J1750−27

Escorial

Wijnands

Ootes

et al. 2019

A&A

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“…Important for the interpretation of the cooling emission in Be/X-ray transients is the fact that it is possible that the observed cooling emission might arise from hot spots at the NS magnetic poles (see Rouco Escorial et al, 2017). However, the rest of the surface could contribute (or dominate) significantly to the cooling radiation, but its lower temperature might make this contribution unobservable (see discussion in Elshamouty et al, 2016b).…”

Section: High-magnetic Field Ns Systemsmentioning

confidence: 99%

Cooling of Accretion-Heated Neutron Stars

2017

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We present a brief, observational review about the study of the cooling behaviour of accretion-heated neutron stars and the inferences about the neutron-star crust and core that have been obtained from these studies. Accretion of matter during outbursts can heat the crust out of thermal equilibrium with the core and after the accretion episodes are over, the crust will cool down until crust-core equilibrium is restored. We discuss the observed properties of the crust cooling sources and what has been learned about the physics of neutron-star crusts. We also briefly discuss those systems that have been observed long after their outbursts were over, i.e, during times when the crust and core are expected to be in thermal equilibrium. The surface temperature is then a direct probe for the core temperature. By comparing the expected temperatures based on estimates of the accretion history of the targets with the observed ones, the physics of neutron-star cores can be investigated. Finally, we discuss similar studies performed for strongly magnetized neutron stars in which the magnetic field might play an important role in the heating and cooling of the neutron stars.Comment: Has appeared in Journal of Astrophysics and Astronomy special issue on 'Physics of Neutron Stars and Related Objects', celebrating the 75th birth-year of G. Srinivasan. In case of missing sources and/or references in the tables, please contact the first author and they will be included in updated versions of this revie

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“…However, sometimes these outbursts are separated by only 1-1.5 yr, and in this case the second outburst is of lower luminosity than the first (e.g. Rouco Escorial et al 2017Escorial et al , 2019. After major outbursts a decrease in the size of the Be star disc is observed (Reig et al , 2016.…”

Section: Introductionmentioning

confidence: 99%

The frequency of Kozai–Lidov disc oscillation driven giant outbursts in Be/X-ray binaries

Martin

Franchini

2019

Monthly Notices of the Royal Astronomical Society

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Giant outbursts of Be/X-ray binaries may occur when a Be-star disc undergoes strong eccentricity growth due to the Kozai-Lidov (KL) mechanism. The KL effect acts on a disc that is highly inclined to the binary orbital plane provided that the disc aspect ratio is sufficiently small. The eccentric disc overflows its Roche lobe and material flows from the Be star disc over to the companion neutron star causing X-ray activity. With N-body simulations and steady state decretion disc models we explore system parameters for which a disc in the Be/X-ray binary 4U 0115+634 is KL unstable and the resulting timescale for the oscillations. We find good agreement between predictions of the model and the observed giant outburst timescale provided that the disc is not completely destroyed by the outburst. This allows the outer disc to be replenished between outbursts and a sufficiently short KL oscillation timescale. An initially eccentric disc has a shorter KL oscillation timescale compared to an initially circular orbit disc. We suggest that the chaotic nature of the outbursts is caused by the sensitivity of the mechanism to the distribution of material within the disc. The outbursts continue provided that the Be star supplies material that is sufficiently misaligned to the binary orbital plane. We generalise our results to Be/X-ray binaries with varying orbital period and find that if the Be star disc is flared, it is more likely to be unstable to KL oscillations in a smaller orbital period binary, in agreement with observations.

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The low-luminosity behaviour of the 4U 0115+63 Be/X-ray transient

Cited by 16 publications

References 47 publications

Quiescent X-ray variability in the neutron star Be/X-ray transient GRO J1750−27

Quiescent X-ray variability in the neutron star Be/X-ray transient GRO J1750−27

Cooling of Accretion-Heated Neutron Stars

The frequency of Kozai–Lidov disc oscillation driven giant outbursts in Be/X-ray binaries

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