Westerlund 1

Westerlund 1
Westerlund 1
Observation data (J2000 epoch)
Constellation	Ara
Right ascension	16h 47m 04.0s
Declination	-45° 51′ 04.9″
Distance	approx. 12000-16000 ly (3500-5000 pc)
Other designations	ARA CLUSTER, Westerlund 1, ESO 277-12, C 1644-457, VDBH 197
See also: Open cluster, List of open clusters

Westerlund 1 (sometimes abbreviated Wd1) is the most massive compact young star cluster known in the local group of galaxies and is about 3.5-5 kpc away from Earth. It was discovered by Bengt Westerlund in 1961^[1] but remained largely unstudied for many years due to high interstellar extinction (absorption) in its direction.

The cluster contains a large number of rare, evolved high-mass stars including 6 yellow hypergiants, 4 red supergiants, 24 Wolf-Rayet stars, a luminous blue variable, many OB supergiants and an unusual sgB[e] star that has been proposed as the remnant of a recent stellar merger^[2]. In addition, X-ray observations have revealed the presence of the magnetar CXO J164710.2-455216 (also known as the Westerlund 1 magnetar), a slow X-ray pulsar that must have formed from a high-mass progenitor star^[3][4]. Westerlund 1 is believed to have formed in a single burst of star formation, implying the constituent stars have the same age and composition.

Besides hosting some of the most massive and least-understood stars in the galaxy, it is useful as an analog to help astronomers determine what occurs within extragalactic super star clusters.

Observations

Westerlund 1 at visible (left) and X-ray (right) wavelengths. Due to the large interstellar reddening the hot, blue OB supergiants appear red, as all the blue light from the stars has been absorbed. The Westerlund 1 magnetar is marked in the X-ray image.

The brightest O7-8V main sequence stars in Wd1 have V-band photometric magnitudes around 20.5, and therefore at visual wavelengths Wd1 is dominated by highly luminous post-Main Sequence stars (V-band magnitudes of 14.5-18, absolute magnitudes -7 to -10), along with less-luminous post-Main Sequence stars of luminosity class Ib and II (V-band magnitudes of 18-20). Due to the extremely high interstellar reddening towards Wd1, it is very difficult to observe in the U- and B-bands, and most observations are made in the R- or I-bands at the red end of the spectrum or in the infra red. Stars in the cluster are generally named using a classification introduced by Westerlund^[5], although a separate naming convention is often used for the Wolf-Rayet stars ^[6].

At X-ray wavelengths, Wd1 shows diffuse emission from interstellar gas and point emission from both high-mass, post-Main Sequence and low mass, pre-Main Sequence stars. The Westerlund 1 magnetar is the most luminous X-ray point source in the cluster, with the sgB[e] star W9, the (presumed) binary W30a and the Wolf-Rayet stars WR A and WR B all strong X-ray sources. Approximately 50 other X-ray point sources are associated with luminous optical counterparts. Finally, at radio wavelengths the sgB[e] star W9 and red supergiants W20 and W26 are strong radio sources, while the majority of the cool hypergiants and a few OB supergiants and Wolf-Rayet stars are also detected.

Age and Evolutionary State

The age of Wd1 is estimated at 4-5Myr from comparison of the population of evolved stars with models of stellar evolution. The presence of significant numbers of both Wolf-Rayet stars and red and yellow supergiants in Wd1 represents a strong constraint on the age: theory suggests that red supergiants will not form until around 4Myr as the most massive stars do not go through a red supergiant phase, while the Wolf-Rayet population declines sharply after 5Myr. This range of ages is broadly consistent with infra-red observations of Wd1 that reveal the presence of late-O main sequence stars, although a lower age of around 3.5Myr has been suggested from observations of lower-mass stars in Wd1 ^[7].

If Wd1 formed stars with a typical initial mass function then the cluster would have originally contained a significant number of very massive stars, such as those currently observed in the younger Arches cluster. Current estimates of the age of Wd1 are greater than the lifetimes of these stars, and stellar evolution models suggest that there would already have been 50-150 supernovae in Wd1, with a supernova rate of approximately one per 10,000 years over the last million years. However, to date only one definitive supernova remnant has been detected - the Westerlund 1 magnetar - and the lack of other compact objects and high-mass X-ray binaries is puzzling. A number of suggestions have been put forward, including high supernova kick velocities that disrupt binary systems, the formation of slowly-accreting (and therefore undetectable) stellar mass black holes, or binary systems in which both objects are now compact objects, but the problem has yet to be resolved.

As the stars in Westerlund 1 have the same age, composition and distance, the cluster represents an ideal environment for understanding the evolution of massive stars. The simultaneous presence of stars evolving on to and off of the Main Sequence presents a robust test for stellar evolution models, which are also currently unable to correctly predict the observed distribution of Wolf-Rayet subtypes in Westerlund 1^[8].

Binary Fraction

A number of lines of evidence point to a high binary fraction amongst the high-mass stars in Wd1. Some massive binaries are detected directly through photometry ^[9] and radial velocity ^[10] observations, while many others are inferred through secondary characteristics (such as high X-ray luminosity, non-thermal radio spectra and excess infra-red emission) that are typical of colliding-wind binaries or dust-forming Wolf-Rayet stars. Overall binary fractions of 70% for the Wolf-Rayet population^[6] and in excess of 40% for the OB supergiants are currently estimated, although both may be incomplete^[10].

Distance and Location

Wd1 is too remote for direct measurement of the distance via parallax measurements, and the distance must be estimated from the expected absolute magnitude of the stars and estimates of the extinction towards the cluster. This has been done for both the yellow hypergiant^[2] and Wolf-Rayet^[6] populations, yielding estimates around 5kpc in both cases, while a determination from the main-sequence population suggests 3.6kpc ^[7]. These estimates all place Wd1 near the outer edge of the Galactic bar, which may be significant in determining how such a massive cluster formed.

The detection of only a limited number of Wolf-Rayet stars at radio wavelengths provides a lower limit on the distance of 2kpc^[2]; while a few Wolf-Rayet stars are detected, these are believed to be colliding-wind binaries with correspondingly enhanced radio emission.

References

1. ^ A Heavily Reddened Cluster in Ara, Westerlund (1961)
2. ^ ^{a b c} On the massive stellar population of the super star cluster Westerlund 1, Clark et al. (2005)
3. ^ Westerlund 1: Neutron Star Discovered Where a Black Hole Was Expected
4. ^ A Neutron Star with a Massive Progenitor in Westerlund 1, Muno et al. (2006)
5. ^ Photometry and spectroscopy of stars in the region of a highly reddened cluster in ARA, Westerlund (1987)
6. ^ ^{a b c} A census of the Wolf-Rayet content in Westerlund 1 from near-infrared imaging and spectroscopy, Crowther et al. (2006)
7. ^ ^{a b} Intermediate to low-mass stellar content of Westerlund 1, Brandner et al. (2008)
8. ^ Westerlund 1 as a Template for Massive Star Evolution, Negueruela et al. (2008)
9. ^ Variability of Young Massive Stars in the Galactic Super Star Cluster Westerlund 1, Bonanos (2007)
10. ^ ^{a b} A VLT/FLAMES survey for massive binaries in Westerlund 1: I. first observations of luminous evolved stars, Ritchie et al. (2009)

See also

• Artist’s impression of a magnetar X-ray satellites catch magnetar in gigantic stellar ‘hiccup’, ESA website, 2007
• Simbad
• Image of Westerlund 1