<p> The conditions ideally suited for blue straggler star formation are for the most part unknown, though there is mounting evidence to suggest that the preferred blue straggler formation pathway, whether it be via the coalescence of a primordial binary system or through the collision of two single main-sequence stars, depends largely on the cluster environment. In this thesis we are trying to isolate the preferred blue straggler formation mechanism(s)
operating in various globular cluster environments by comparing relative blue straggler frequencies to global cluster properties.</p> <p> We define a series of selection rules to isolate the blue stragglers from main-sequence turn-off and extended horizontal branch stars in the colour-magnitude diagrams of 57 globular clusters taken from HST images of their
central cores. The boundary conditions were defined using only the main-sequence turn-off as a point of reference, and are hence applied consistently from cluster to cluster. We chose to count only those stars found within one core radius of the cluster center in an effort to obtain a sample that is approximately representative of a uniform cluster environment where, ideally, a single blue straggler formation mechanism is predominantly operating. Relative frequencies
of blue straggler stars are then found using the red giant branch for normalization and are subsequently analyzed. We confirm the anticorrelation between relative blue straggler frequency and total integrated cluster luminosity previously observed by Piotto et al. (2004), and find a new anticorrelation between relative blue straggler frequency and the central velocity dispersion, as well as a weak anticorrelation with the half-mass relaxation time. We find no other statistically significant trends. Observational implications pertaining to blue straggler formation mechanisms are then discussed.</p> <p> We present a very simple, semi-analytic model designed in an attempt to reproduce the observed trends in the core. Using estimates for the collisional timescales, we find that only a small percentage of the blue stragglers produced are a direct result of collisions. The majority of the blue stragglers created
in our model are thus products of mass-transfer in tight, low-mass binary systems. We were surprised to find a reasonably good agreement between the data and our predictions, given the simplicity of our model. Our results suggest that the binary fraction could be a crucial parameter in shaping blue straggler populations, and hence better and more abundant observations of binary systems and their numbers could prove an important step in gaining a
better understanding of blue straggler formation mechanisms.</p> / Thesis / Master of Science (MSc)
| Identifer | oai:union.ndltd.org:mcmaster.ca/oai:macsphere.mcmaster.ca:11375/21607 |
| Date | 05 1900 |
| Creators | Leigh, Nathan W. C. |
| Contributors | Sills, Alison, Physics and Astronomy |
| Source Sets | McMaster University |
| Language | en_US |
| Detected Language | English |
| Type | Thesis |
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