Your search keyword '"In T Zand, J. J. M."' showing total 5 results

1. A catalogue of unusually long thermonuclear bursts on neutron stars.

Author

Alizai, K, Chenevez, J, Cumming, A, Degenaar, N, Falanga, M, Galloway, D K, in 't Zand, J J M, Jaisawal, G K, Keek, L, Kuulkers, E, Lampe, N, Schatz, H, and Serino, M

Subjects

NEUTRON stars, X-ray bursts, X-ray binaries, GAMMA ray bursts, CATALOGS, STELLAR photospheres, CATALOGING

Abstract

Rare, energetic (long) thermonuclear (Type I) X-ray bursts are classified either as intermediate-duration or 'supern' bursts, based on their duration. Intermediate-duration bursts lasting a few to tens of minutes are thought to arise from the thermonuclear runaway of a relatively thick (≈1010 g cm−2) helium layer, while superbursts lasting hours are attributed to the detonation of an underlying carbon layer. We present a catalogue of 84 long thermonuclear bursts from 40 low-mass X-ray binaries, and defined from a new set of criteria distinguishing them from the more frequent short bursts. The three criteria are: (1) a total energy release longer than 1040 erg, (2) a photospheric radius expansion phase longer than 10 s, and (3) a burst time-scale longer than 70 s. This work is based on a comprehensive systematic analysis of 70 bursts found with INTEGRAL, RXTE, Swift, BeppoSAX, MAXI , and NICER , as well as 14 long bursts from the literature that were detected with earlier generations of X-ray instruments. For each burst, we measure its peak flux and fluence, which eventually allows us to confirm the distinction between intermediate-duration bursts and superbursts. Additionally, we list 18 bursts that only partially meet the above inclusion criteria, possibly bridging the gap between normal and intermediate-duration bursts. With this catalogue, we significantly increase the number of long-duration bursts included in the MINBAR and thereby provide a substantial sample of these rare X-ray bursts for further study. [ABSTRACT FROM AUTHOR]

Published

2023

2. The Swift Bulge Survey: optical and near-IR follow-up featuring a likely symbiotic X-ray binary and a focused wind CV.

Author

Shaw, A W, Heinke, C O, Maccarone, T J, Sivakoff, G R, Strader, J, Bahramian, A, Degenaar, N, Kennea, J A, Kuulkers, E, Rau, A, Rivera Sandoval, L E, Shishkovsky, L, Swihart, S J, Tetarenko, A J, Wijnands, R, and in 't Zand, J J M

Subjects

X-ray binaries, GALACTIC X-ray sources, X-ray bursts, GIANT stars, NEUTRON stars, BINARY stars, PAIR production

Abstract

The nature of very faint X-ray transients (VFXTs) – transient X-ray sources that peak at luminosities |$L_X\lesssim 10^{36} {\rm \, erg \, s^{-1}}$| – is poorly understood. The faint and often short-lived outbursts make characterizing VFXTs and their multiwavelength counterparts difficult. In 2017 April we initiated the Swift Bulge Survey, a shallow X-ray survey of ∼16 square degrees around the Galactic centre with the Neil Gehrels Swift Observatory. The survey has been designed to detect new and known VFXTs, with follow-up programmes arranged to study their multiwavelength counterparts. Here we detail the optical and near-infrared follow-up of four sources detected in the first year of the Swift Bulge Survey. The known neutron star binary IGR J17445-2747 has a K4III donor, indicating a potential symbiotic X-ray binary nature and the first such source to show X-ray bursts. We also find one nearby M-dwarf (1SXPS J174215.0-291453) and one system without a clear near-IR counterpart (Swift J175233.9-290952). Finally, 3XMM J174417.2-293944 has a subgiant donor, an 8.7 d orbital period, and a likely white dwarf accretor; we argue that this is the first detection of a white dwarf accreting from a gravitationally focused wind. A key finding of our follow-up campaign is that binaries containing (sub)giant stars may make a substantial contribution to the VFXT population. [ABSTRACT FROM AUTHOR]

Published

2020

3. XMMU J181227.8–181234: a new ultracompact X-ray binary candidate.

Author

Goodwin, A J, Galloway, D K, in 't Zand, J J M, Kuulkers, E, Bilous, A, and Keek, L

Subjects

X-ray binaries, GAMMA ray bursts, X-ray bursts, NEUTRON stars, EDDINGTON mass limit, NEUTRON sources

Abstract

We report the discovery of Type I (thermonuclear) X-ray bursts from the transient source XMMU J181227.8–181234 = XTE J1812–182. We found seven X-ray bursts in Rossi X-ray Timing Explorer observations during the 2008 outburst, confirming the source as a neutron star low-mass X-ray binary. Based on the measured burst fluence and the average recurrence time of 1.4 |$^{+0.9}_{-0.5}$|  h, we deduce that the source is accreting almost pure helium (X ≤ 0.1) fuel. Two bursts occurred just 18 min apart; the first short waiting time bursts observed in a source accreting hydrogen-poor fuel. Taking into consideration the effects on the burst and persistent flux due to the inferred system inclination of 30 ± 10°, we estimate the distance to be 14 ± 2 kpc, where we report the statistical uncertainty but note that there could be up to |$20{{\ \rm per\ cent}}$| variation in the distance due to systematic effects discussed in the paper. The corresponding maximum accretion rate is 0.30 ± 0.05 times the Eddington limit. Based on the low hydrogen content of the accreted fuel and the short average recurrence time, we classify the source as a transient ultracompact low-mass X-ray binary. [ABSTRACT FROM AUTHOR]

Published

2019

4. Indications for a slow rotator in the Rapid Burster from its thermonuclear bursting behaviour.

Author

Bagnoli, T., in ’t Zand, J. J. M., Galloway, D. K., and Watts, A. L.

Subjects

*THERMONUCLEAR reactions in stars, *BINARY stars, *NEUTRON stars, *X-ray bursts, *EDDINGTON mass limit

Abstract

We perform time-resolved spectroscopy of all the type I bursts from the Rapid Burster (MXB 1730−335) detected with the Rossi X-Ray Timing Explorer. Type I bursts are detected at high accretion rates, up to ≃45 per cent of the Eddington luminosity. We find evidence that bursts lacking the canonical cooling in their time-resolved spectra are, nonetheless, thermonuclear in nature. The type I bursting rate keeps increasing with the persistent luminosity, well above the threshold at which it is known to abruptly drop in other bursting low-mass X-ray binaries. The only other known source in which the bursting rate keeps increasing over such a large range of mass accretion rates is the 11 Hz pulsar IGR J17480−2446. This may indicate a similarly slow spin for the neutron star in the Rapid Burster. [ABSTRACT FROM AUTHOR]

Published

2013

5. Puzzling thermonuclear burst behaviour from the transient low-mass X-ray binary IGR J17473−2721.

Author

Chenevez, J., Altamirano, D., Galloway, D. K., in 't Zand, J. J. M., Kuulkers, E., Degenaar, N., Falanga, M., Monte, E. Del, Evangelista, Y., Feroci, M., and Costa, E.

Subjects

LOW mass stars, X-ray binaries, X-ray bursts, ACCRETION (Astrophysics), FIELD emission, NEUTRON stars, ASTROPHYSICS

Abstract

We investigate the thermonuclear bursting behaviour of IGR J2721, an X-ray transient that in 2008 underwent a 6-month long outburst, starting (unusually) with an X-ray burst. We detected a total of 57 thermonuclear bursts throughout the outburst with AGILE, Swift, Rossi X-ray Timing Explorer ( RXTE) and the INTErnational Gamma-Ray Astrophysics Laboratory (INTEGRAL). The wide range of inferred accretion rates (between <1 and ≃20 per cent of the Eddington accretion rate ) spanned during the outburst allows us to study changes in the nuclear burning processes and to identify up to seven different phases. The burst rate increased gradually with the accretion rate until it dropped (at a persistent flux corresponding to ≃15 per cent of ) a few days before the outburst peak, after which bursts were not detected for a month. As the persistent emission subsequently decreased, the bursting activity resumed at a much lower rate than during the outburst rise. This hysteresis may arise from the thermal effect of the accretion on the surface nuclear burning processes, and the time-scale is roughly consistent with that expected for the neutron star crust thermal response. On the other hand, an undetected 'superburst', occurring within a data gap near the outburst peak, could have produced a similar quenching of burst activity. [ABSTRACT FROM AUTHOR]

Published

2011