ON THE ORIGIN OF THE NEAR-INFRARED EMISSION FROM THE NEUTRON-STAR LOW-MASS X-RAY BINARY GX 9+1

We have determined an improved position for the luminous persistent neutron-star low-mass X-ray binary and atoll source GX 9+1 from archival Chandra X-ray Observatory data. The new position significantly differs from a previously published Chandra position for this source. Based on the revised X-ray position we have identified a new near-infrared (NIR) counterpart to GX 9+1 in K[subscript s]-band images obtained with the PANIC and FourStar cameras on the Magellan Baade Telescope. NIR spectra of this K[subscript s]=16.5 ± 0.1 mag star, taken with the FIRE spectrograph on the Baade Telescope, show a strong Br γ emission line, which is a clear signature that we discovered the true NIR counterpart to GX 9+1. The mass donor in GX 9+1 cannot be a late-type giant, as such a star would be brighter than the estimated absolute Ks magnitude of the NIR counterpart. The slope of the dereddened NIR spectrum is poorly constrained due to uncertainties in the column density NH and NIR extinction. Considering the source's distance and X-ray luminosity, we argue that NH likely lies near the high end of the previously suggested range. If this is indeed the case, the NIR spectrum is consistent with thermal emission from a heated accretion disk, possibly with a contribution from the secondary. In this respect, GX 9+1 is similar to other bright atolls and the Z sources, whose NIR spectra do not show the slope that is expected for a dominant contribution from optically thin synchrotron emission from the inner regions of a jet

Discovery of the near-infrared counterpart to the luminous neutron-star low-mass X-ray binary GX 3+1

Using the High Resolution Camera onboard the Chandra X-ray Observatory, we have measured an accurate position for the bright persistent neutron-star X-ray binary and atoll source GX 3+1. At a location that is consistent with this new position we have discovered the near-infrared (NIR) counterpart to GX 3+1 in images taken with the PANIC and FourStar cameras on the Magellan Baade Telescope. The identification of this K_s=15.8+-0.1 mag star as the counterpart is based on the presence of a Br-gamma emission line in a NIR spectrum taken with the FIRE spectrograph on the Baade Telescope. The absolute magnitude derived from the best available distance estimate to GX 3+1 indicates that the mass donor in the system is not a late-type giant. We find that the NIR light in GX 3+1 is likely dominated by the contribution from a heated outer accretion disk. This is similar to what has been found for the NIR flux from the brighter class of Z sources, but unlike the behavior of atolls fainter (Lx ~ 1e36 to 1e37 erg/s) than GX 3+1, where optically-thin synchrotron emission from a jet probably dominates the NIR flux.Comment: Accepted for publication in Ap

A Chandra X-ray census of the interacting binaries in old open clusters - NGC188

We present a new X-ray study of NGC188, one of the oldest open clusters known in our Galaxy (7 Gyr). Our observation with the Chandra X-ray Observatory is aimed at uncovering the population of close interacting binaries in NGC188. We detect 84 sources down to a luminosity of Lx ~ 4e29 erg/s (0.3-7 keV), of which 73 are within the half-mass radius rh. Of the 60 sources inside rh with more than 5 counts, we estimate that ~38 are background sources. We detected 55 new sources, and confirmed 29 sources previously detected by ROSAT and/or XMM-Newton. A total of 13 sources detected are cluster members, and 7 of these are new detections: four active binaries, two blue straggler stars (BSSs), and, surprisingly, an apparently single cluster member on the main sequence (CX33/WOCS5639). One of the BSSs detected (CX84/WOCS5379) is intriguing as its X-ray luminosity cannot be explained by its currently understood configuration as a BSS/white-dwarf binary in an eccentric orbit of ~120 days. Its X-ray detection, combined with reports of short-period optical variability, suggests the presence of a close binary, which would make this BSS system a hierarchical multiple. We also classify one source as a new cataclysmic-variable candidate; it is identified with a known short-period optical variable, whose membership to NGC188 is unknown. We have compared the X-ray emissivity of NGC188 with those of other old Galactic open clusters. Our findings confirm the earlier result that old open clusters have higher X-ray emissivities than other old stellar populations.Comment: Accepted for publication in MNRA

Discovery of a Significant Magnetic CV Population in the Limiting Window

[Abridged] We have discovered 10 periodic X-ray sources from the 1 Ms Chandra ACIS observation of the Limiting Window (LW), a low extinction region (A_V~3.9) at 1.4 Deg south of the Galactic center. The observed periods (~1.3 to 3.4 hours) and the X-ray luminosities (10^{31.8-32.9} erg s^-1 at 8 kpc) of the 10 periodic sources, combined with the lack of bright optical counterparts and thus high X-ray-to-optical flux ratios, suggest that they are likely accreting binaries, in particular, magnetic cataclysmic variables (MCVs). All of the 10 sources exhibit a relatively hard X-ray spectrum (PLI<2 for a power law model) and X-ray spectra of at least five show an extinction larger than the field average expected from the interstellar medium in the region. The discovery of these periodic X-ray sources in the LW further supports the current view that MCVs constitute the majority of low luminosity hard X-ray sources (~10^{30-33} erg s^-1) in the Bulge. The period distribution of these sources resembles those of polars, whereas the relatively hard spectra suggest that they could be intermediate polars (IPs). These puzzling properties can be explained by unusual polars with buried magnetic fields or a rare sub-class of MCVs, nearly synchronous MCVs. These unusual MCVs may provide important clues in the evolutionary path of MCVs from IPs to polars. The completeness simulation indicates >~40% of the hard X-ray sources in the LW are periodic. Therefore, this discovery provides a first direct evidence of a large MCV population in the Bulge.Comment: 15 pages, 10 figures, 5 tables, submitted to ApJ, revised in response to the referee's revie

A Massive Neutron Star in the Globular Cluster M5

We report the results of 19 years of Arecibo timing for two pulsars in the globular cluster NGC 5904 (M5), PSR B1516+02A (M5A) and PSR B1516+02B (M5B). This has resulted in the measurement of the proper motions of these pulsars and, by extension, that of the cluster itself. M5B is a 7.95-ms pulsar in a binary system with a > 0.13 solar mass companion and an orbital period of 6.86 days. In deep HST images, no optical counterpart is detected within ~2.5 sigma of the position of the pulsar, implying that the companion is either a white dwarf or a low-mass main-sequence star. The eccentricity of the orbit (e = 0.14) has allowed a measurement of the rate of advance of periastron: (0.0142 +/-0.0007) degrees per year. We argue that it is very likely that this periastron advance is due to the effects of general relativity, the total mass of the binary system then being 2.29 +/-0.17 solar masses. The small measured mass function implies, in a statistical sense, that a very large fraction of this total mass is contained in the pulsar: 2.08 +/- 0.19 solar masses (1 sigma); there is a 5% probability that the mass of this object is < 1.72 solar masses and a 0.77% probability that is is between 1.2 and 1.44 solar masses. Confirmation of the median mass for this neutron star would exclude most ``soft'' equations of state for dense neutron matter. Millisecond pulsars (MSPs) appear to have a much wider mass distribution than is found in double neutron star systems; about half of these objects are significantly more massive than 1.44 solar masses. A possible cause is the much longer episode of mass accretion necessary to recycle a MSP, which in some cases corresponds to a much larger mass transfer.Comment: 10 pages in ApJ emulate format, 2 tables, 6 figures. Added February 2008 data, slightly revised mass limits. Accepted for publication in Ap

Optical studies of X-ray sources in the old open cluster M67

M67 is an old open star cluster with an estimated age of ~4 billion years. It is one of the best studied open clusters. This thesis contains an optical study of X- ray sources in M67; in addition several sources in the old clusters NGC752 and NGC6940 are studied. X-ray observations of old open clusters have detected many magnetically active binaries. This is not unexpected: at ages higher than ~1 billion years single late-type stars are believed to rotate too slowly to emit detectable X-rays. Tidal interaction in a close binary is therefore required to induce rotation at a higher rate than is typical for single stars. However, in this work I mainly studied stars whose X-rays are not as easily explained: binaries with orbits too wide for tidal interaction, and stars whose evolutionary statuses are badly understood; in these cases the X-rays might provide a clue to the nature of the stars. Many of the peculiar X-ray sources that I investigated are binaries. It is found that the properties of some systems are difficult to understand in the context of binary evolution alone. Therefore, one of the conclusions is that interactions between cluster stars have produced these peculiar systems and that the properties of the stars that are the outcome of such interactions are still poorly understood. One of the stars that is studied in detail is the blue straggler S 1082 in M67 which is probably a good example of a system that is the product of one or multiple encounters. The present study solved its apparently contradictory properties: eclipses with a period of ~1 day had been observed but the radial- velocity variations of the narrow lines in the spectrum indicate that the star moves in an orbit of ~1000 days. We concluded that S 1082 must be triple, and indeed found the signature of three stars. As we find that two stars in the system are blue stragglers on their own account and that the total mass of the inner binary is about three times the turnoff mass of M67, probably five stars were involved in the formation of S 1082. Two other stars in M67 that are studied are the sub-subgiants S 1063 and S 1113. Even though the peculiar positions of these binaries in the colour- magnitude diagram are so similar, we found that their different orbital properties make it difficult to find one explanation for their origin. In fact, we have great difficulty to explain the properties of these stars at all, and are left to conclude that they were involved in a recent interaction with other cluster stars