Discovery of the Neutron Star Spin Frequency in EXO 0748-676

Villarreal, Adam R.; Strohmayer, Tod E.

doi:10.1086/425737

Cited by 82 publications

(106 citation statements)

References 20 publications

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“…Larger spin rates, assuming a NS radius of around 10 km, would wash out such a line unless the surface emission is confined to a narrow region around the spin axis ( Bhattacharyya et al 2004). A slow rotation rate for EXO 0748À676 is consistent with the recently measured 44.7 Hz burst oscillation ( Villarreal & Strohmayer 2004). With these line profiles in hand, and assuming that the burst oscillation of 44.7 Hz is the rotation rate of the NS, detailed fits to the data raise the exciting prospect of fitting for the NS radius (Chang et al 2005).…”

Section: Discussionsupporting

confidence: 78%

Formation of Resonant Atomic Lines during Thermonuclear Flashes on Neutron Stars

Chang

Bildsten

Wasserman

2005

ApJ

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Motivated by the measurement of redshifted Fe H lines during type I X-ray bursts on EXO 0748À676 (Cottam, Paerels, & Mendez), we study the formation of atomic Fe lines above the photosphere of a bursting neutron star (k B T eA % 1 2 keV). We discuss the effects of Stark broadening, resonant scattering, and NLTE (level population) on the formation of hydrogenic Fe H, Ly, and Pa lines. From the observed equivalent width (EW) of the Fe H line, we find an implied Fe column of 1 3 ð Þ; 10 20 cm À2 , which is 3-10 times larger than the Fe column calculated from the accretion/spallation model of Bildsten, Chang, & Paerels. We also estimate that the implied Fe column is about a factor of 2-3 larger than a uniform solar metallicity atmosphere. We discuss the effects of rotational broadening and find that the rotation rate of EXO 0748À676 must be slow, as confirmed by the recent measurement of a 45 Hz burst oscillation by Villareal & Strohmayer. We also show that the Fe Ly EW % 15 20 eV (redshifted 11-15 eV) and the Pa EW % 4 7 eV (redshifted 3-5 eV) when the H EW is 10 eV (redshifted 8 eV). The Ly line is rotationally broadened to a depth of %10%, making it difficult to observe with Chandra. We also show that radiative levitation can likely support the Fe column needed to explain the line.

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Section: Discussionsupporting

confidence: 78%

Formation of Resonant Atomic Lines during Thermonuclear Flashes on Neutron Stars

Chang

Bildsten

Wasserman

2005

ApJ

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“…We confirm the finding of Villarreal & Strohmayer (2004), that the widths of these features are consistent with formation at the surface of a star with a spin rate of 45 Hz. We have also shown that stars with spin rates up to $600 Hz can produce lines this narrow if emission from close to the rotational axis dominates.…”

Section: Discussionsupporting

confidence: 90%

The Shapes of Atomic Lines from the Surfaces of Weakly Magnetic Rotating Neutron Stars and Their Implications

Bhattacharyya

Miller

Lamb

2006

ApJ

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Motivated by the report by Cottam et al. of iron resonance scattering lines in the spectra of thermonuclear bursts from EXO 0748À676, we have investigated the information about neutron star structure and the geometry of the emission region that can be obtained by analyzing the profiles of atomic lines formed at the surface of the star. We have calculated the detailed profiles of such lines, taking into account the star's spin and the full effects of special and general relativity, including light bending and frame dragging. We discuss the line shapes produced by rotational Doppler broadening and magnetic splitting of atomic lines for the spin rates and magnetic fields expected in neutron stars in low-mass X-ray binary systems. We show that narrow lines are possible even for rapidly spinning stars if the emission region or the line of sight are close to the spin axis. For most neutron stars in low-mass systems, magnetic splitting is too small to obscure the effects of special and general relativity. We show that the ratio of the star's mass to its equatorial radius can be determined to within 5% using atomic line profiles, even if the lines are broad and skewed. This is the precision required to constrain strongly the equation of state of neutron star matter. We show further that if the radius and latitude of emission are known to $5%-10% accuracy, then frame dragging has a potentially detectable effect on the profiles of atomic lines formed at the stellar surface.

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“…First, it is detected in the brightest burst with significance at the 99.96% confidence level, not in a whole set of six bursts (Kaaret et al 2007). Second, from a statistical point of view, the frequency of 1122 Hz is too far outside the range of the previously known spin frequencies of LMXBs, from the minimum value of 45 Hz (Villarreal & Strohmayer 2004) to the maximum of 619 Hz (Hartman et al 2003), centered at ∼400 Hz , and it is much higher than the fastest spin frequency of radio pulsars, 716 Hz (Hessels et al 2006). Therefore, we take this spin frequency of 1122 Hz as a tentative detection, or the possibility might be considered that the signal of 1122 Hz is merely a candidate burst oscillation (e.g., Galloway 2007 By means of this assumed highest spin frequency, we can constrain the NS mass and radius, which indicates the frequency of 1122 Hz to be close to the centrifugal breakup limit for some equations of state of nuclear matter (e.g., Burgio et al 2003).…”

Section: Consequences and Discussionmentioning

confidence: 85%

Does Submillisecond Pulsar XTE J1739−285 Contain a Weak Magnetic Neutron Star or Quark Star?

Zhang¹,

Yin²,

Zhao³

et al. 2007

PUBL ASTRON SOC PAC

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ABSTRACT. The possible detection of the fastest spinning nuclear-powered pulsar XTE J1739Ϫ285, of frequency 1122 Hz (0.8913 ms), arouses us to constrain the mass and radius of its central compact object and to infer the stellar matter composition: neutrons or quarks. Spun up by the accreting materials to such a high rotating speed, the compact star should have either a small radius or short innermost stable circular orbit. By the empirical relation between the upper kilohertz quasi-periodic oscillation frequency and star spin frequency, a strong constraint on mass and radius is obtained of 1.51 M , and 10.9 km, respectively, which excludes most equations of state (EOSs) of normal neutrons and strongly hints the star promisingly to be a strange quark star. Furthermore, the star magnetic field is estimated to be about , which reconciles with those 7 94 # 10 G ! B ! 10 G of millisecond radio pulsars, revealing the clues of the evolution linkage of two types of astrophysical objects.

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Discovery of the Neutron Star Spin Frequency in EXO 0748-676

Cited by 82 publications

References 20 publications

Formation of Resonant Atomic Lines during Thermonuclear Flashes on Neutron Stars

Formation of Resonant Atomic Lines during Thermonuclear Flashes on Neutron Stars

The Shapes of Atomic Lines from the Surfaces of Weakly Magnetic Rotating Neutron Stars and Their Implications

Does Submillisecond Pulsar XTE J1739−285 Contain a Weak Magnetic Neutron Star or Quark Star?

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