Title: Spectral and timing properties of IGR J00291+5934 during its 2015 outburst Author: A. Sanna, F. Pintore, E. Bozzo, C. Ferrigno, A. Papitto, A. Riggio, T. Di Salvo, R. Iaria, A. D'Aì, E. Egron, L. Burderi
We report on the spectral and timing properties of the accreting millisecond X-ray pulsar IGR J00291+5934 observed by XMM-Newton and NuSTAR during its 2015 outburst. The source is in a hard state dominated at high energies by a comptonization of soft photons (~0.9 keV) by an electron population with kTe~30 keV, and at lower energies by a blackbody component with kT~0.5 keV. A moderately broad, neutral Fe emission line and four narrow absorption lines are also found. By investigating the pulse phase evolution, we derived the best-fitting orbital solution for the 2015 outburst. Comparing the updated ephemeris with those of the previous outbursts, we set a 3sigma confidence level interval -6.6 x 10^-13 s/s <P_orb<6.5 x 10^-13 s/s on the orbital period derivative. Moreover, we investigated the pulse profile dependence on energy finding a peculiar behaviour of the pulse fractional amplitude and lags as a function of energy. We performed a phase-resolved spectroscopy showing that the blackbody component tracks remarkably well the pulse-profile, indicating that this component resides at the neutron star surface (hot-spot).
Title: The 2015 outburst of the accretion-powered pulsar IGR J00291+5934: INTEGRAL and Swift observations Author: V. De Falco, L. Kuiper, E. Bozzo, D. K. Galloway, J. Poutanen, C. Ferrigno, L. Stella, M. Falanga
IGR J00291+5934 is the fastest-known accretion-powered X-ray pulsar, discovered during a transient outburst in 2004. In this paper, we report on Integral and Swift observations during the 2015 outburst, which lasts for ~25 d. The source has not been observed in outburst since 2008, suggesting that the long-term accretion rate has decreased by a factor of two since discovery. The averaged broad-band (0.1 - 250 keV) persistent spectrum in 2015 is well described by a thermal Comptonization model with a column density of N_H \approx 4 x 10^21 cm^-2, a plasma temperature of k_Te \approx 50 keV, and a Thomson optical depth of tau_T \approx 1. Pulsations at the known spin period of the source are detected in the Integral data up to the ~150 keV energy band. We also report on the discovery of the first thermonuclear burst observed from IGR J00291+5934, which lasts around 7 min and occurs at a persistent emission level corresponding to roughly 1.6%of the Eddington accretion rate. The properties of the burst suggest it is powered primarily by helium ignited at a depth of y_ign \approx 1.5 x 10^9 g cm^-2 following the exhaustion by steady burning of the accreted hydrogen. The Swift/BAT data from the first ~20 s of the burst provide indications of a photospheric radius expansion phase. Assuming this is the case, we infer a source distance of d=4.2±0.3 kpc.
ESA's Integral space observatory, together with NASA's Rossi X-ray Timing Explorer spacecraft, has found a fast-spinning pulsar in the process of devouring its companion.
Expand (547kb, 2880 x 1944) This is an artist's impression of a pulsar, approximately 20 kilometres in diameter, accreting material from a companion star. The strong gravity from the dense pulsar attracts material from the companion. The flow of gas from the companion to the pulsar is energetic and glows in X-ray light.
This finding supports the theory that the fastest-spinning isolated pulsars get that fast by cannibalising a nearby star. Gas ripped from the companion fuels the pulsar's acceleration. This is the sixth pulsar known in such an arrangement, and it represents a 'stepping stone' in the evolution of slower-spinning binary pulsars into faster-spinning isolated pulsars.
"We're getting to the point where we can look at any fast-spinning, isolated pulsar and say, 'That guy used to have a companion'" - Dr Maurizio Falanga, who led the Integral observations, at the Commissariat a l'Energie Atomique (CEA) in Saclay, France.
'Pulsars' are rotating neutron stars, which are created in stellar explosions. They are the remnants of stars that were once at least eight times more massive than the Sun. These stars still contain about the mass of our Sun compactified into a sphere of only about 20 kilometres across. This pulsar, called IGR J00291+5934, belongs to a category of 'X-ray millisecond pulsars', which pulse with the X-ray light several hundred times a second, one of the fastest known. It has a period of 1.67 milliseconds which is much smaller that most other pulsars that rotate once every few seconds.
Neutron stars are born rapidly spinning in collapses of massive stars. They gradually slow down after a few hundred thousand years. Neutron stars in binary star systems, however, can reverse this trend and speed up with the help from the companion star. For the first time ever, this speeding-up has been observed in the act.
"We now have direct evidence for the star spinning faster whilst cannibalising its companion, something which no one had ever seen before for such a system" - Dr Lucien Kuiper, Netherlands Institute for Space Research (SRON), in Utrecht.
A neutron star can remove gas from its companion star in a process called 'accretion'. The flow of gas onto the neutron star makes the star spin faster and faster. Both the flow of gas and its crashing upon the neutron star surface releases much energy in the form of X-ray and gamma radiation. Neutron stars have such a strong gravitational field that light passing by the star changes its direction by almost 100 degrees (in comparison light passing by the Sun is deflected by an angle which is 200 thousands times smaller).
"This 'gravitational bending' allows us to see the back side of the star" - Prof. Juri Poutanen, University of Oulu, Finland.
"This object was about ten times more energetic than what is usually observed for similar sources. Only some kind of monster emits at these energies, which corresponds to a temperature of almost a billion degrees" - Dr Maurizio Falanga.
From a previous Integral result, scientists deduced that because the neutron star has a strong magnetic field, charged particles from its companion are channelled along the magnetic field lines until they slam into the neutron star surface at one of its magnetic poles, forming 'hot spots'. The very high temperatures seen by Integral arise from this very hot plasma over the accretion spots.
Position(2000): RA 00 29 03.06 Dec +59 34 19.0
IGR J00291+5934 was discovered by Integral during a routine scan of the sky on 2 December 2004, in the outer reaches of our Milky Way galaxy, when it suddenly flared. On the day after, scientists accurately clocked the neutron star with the Rossi X-ray Timing Explorer. Rossi observations revealed that the companion is already a fraction the size of our Sun, perhaps as small as 40 Jupiter masses. The binary orbit is 2.5 hours long (as opposed to the year long Earth-Sun orbit). The full system is very tight; both stars are so close that they will fit into the radius of the Sun. These details support the theory that the two stars are close enough for accretion to take place and that the companion star is being cannibalised.
"Accretion is expected to cease after a billion of years or so. This Integral-Rossi discovery provides more evidence of how pulsars evolve from one phase to another - from an initially slowly spinning binary neutron star emitting high energies, to a rapidly spinning isolated pulsar emitting in radio wavelengths" - Dr Duncan Galloway, Massachusetts Institute of Technology, USA, responsible for the Rossi observations.
The discovery is the first of its kind for Integral (four of the first five rapidly spinning X-ray pulsars were discovered by Rossi). This bodes well in the combined search for these rare objects. Integral’s sensitive detectors can identify relatively dim and distant sources and so, knowing where to look, Rossi can provide timing information through a dedicated observation extending over the entire two-week period of the typical outburst.