Bibcode
Kuulkers, E.; in't Zand, J. J. M.; Atteia, J.-L.; Levine, A. M.; Brandt, S.; Smith, D. A.; Linares, M.; Falanga, M.; Sánchez-Fernández, C.; Markwardt, C. B.; Strohmayer, T. E.; Cumming, A.; Suzuki, M.
Bibliographical reference
Astronomy and Astrophysics, Volume 514, id.A65
Advertised on:
5
2010
Journal
Citations
74
Refereed citations
70
Description
The low-mass X-ray binary 4U 0614+091 is a source of sporadic
thermonuclear (type I) X-ray bursts. We find bursts with a wide variety
of characteristics in serendipitous wide-field X-ray observations by the
WATCH on EURECA, the ASM on RXTE, the WFCs on BeppoSAX, the FREGATE on
HETE-2, the IBIS/ISGRI on INTEGRAL, and the BAT on Swift, as well as
pointed observations with the PCA and HEXTE on RXTE. Most of the bursts
are bright, i.e., they reach a peak flux of about 15 Crab, but a few are
weak and only reach a peak flux below a Crab. One of the bursts shows a
very strong photospheric radius-expansion phase. This allows us to
evaluate the distance to the source, which we estimate to be 3.2 kpc.
The burst durations vary generally from about 10 s to 5 min. However,
after one of the intermediate-duration bursts, a faint tail is seen to
at least about 2.4 h after the start of the burst. One very long burst
was observed, which lasted for several hours. This superburst candidate
was followed by a normal type-I burst only 19 days later. This is, to
our knowledge, the shortest burst-quench time among the superbursters.
The observation of a superburst in this system is difficult to reconcile
if the system is accreting at about 1% of the Eddington limit. We
describe the burst properties in relation to the persistent emission. No
strong correlations are apparent, except that the intermediate-duration
bursts occurred when 4U 0614+091's persistent emission was lowest and
calm, and when bursts were infrequent (on average roughly one every
month to 3 months). The average burst rate increased significantly after
this period. The maximum average burst recurrence rate is about once
every week to 2 weeks. The burst behaviour may be partly understood if
there is at least an appreciable amount of helium present in the
accreted material from the donor star. If the system is an ultra-compact
X-ray binary with a CO white-dwarf donor, as has been suggested, this is
unexpected. If the bursts are powered by helium, we find that the energy
production per accumulated mass is about 2.5 times less than expected
for pure helium matter.