The observers' view of (very) long x-ray bursts: they are super!

In many X-ray point sources on the sky, the X-ray emission arises because hydrogen and/or helium is accreted onto a neutron star from a nearby donor star. When this matter settles on the neutron star surface, it will undergo nuclear fusion. For a large range of physical parameters the fusion is unstable. The resulting thermo-nuclear explosions last from seconds to minutes. They are observed as short flares in X-rays and are called `type I X-ray bursts'. Recently, hours-long X-ray flares have been found in seven X-ray burst sources with the BeppoSAX/WFC, RXTE/ASM and RXTE/PCA. They have similar properties to the usual X-ray bursts, except they last for two or three orders of magnitude longer (hence they are referred to as `superbursts'). This can not be understood in the context of the standard nuclear-fusion picture mentioned above. Instead, the superbursts are thought to be related to the unstable burning of the leftovers from the hydrogen and/or helium fusion. I will discuss the observational properties of these superbursts.

References(4)

Figures(0)

Models of type I x-ray bursts in 4u 1820-30

Andrew Cumming

- Astrophys.J. 595 (2003) 1077-1085
•
e-Print:
- astro-ph/0306245
•
DOI:
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The stability of material accreting onto a neutron star

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e-Print:
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•
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Tod Strohmayer
(
- NASA, Goddard
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,
Lars Bildsten
(
- Santa Barbara, KITP
)

e-Print:
- astro-ph/0301544

Models for type I x-ray bursts with improved nuclear physics

S.E. Woosley
(
- UC, Santa Cruz
)
,
A. Heger
(
- Chicago U., Astron. Astrophys. Ctr.
)
,
Andrew Cumming
(
- UC, Santa Cruz
)
,
R.D. Hoffman
(
- LLNL, Livermore
)
,
J. Pruet
(
- LLNL, Livermore
)

et al.

- Astrophys.J.Suppl. 151 (2004) 75
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e-Print:
- astro-ph/0307425
•
DOI:
- 10.1086/381533