Spelling suggestions: "subject:"globular clusters"" "subject:"lobular clusters""
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Searching For New Long-Period Variable Stars in the Globular Cluster M107Chapman, Justin 29 August 2022 (has links)
No description available.
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Determining the Size of a Galaxy's Globular Cluster Population through Imputation of Incomplete Data with Measurement UncertaintyRichard, Michael R. 11 1900 (has links)
A globular cluster is a collection of stars that orbits the center of its galaxy as a
single satellite. Understanding what influences the formations of these clusters provides understanding of galaxy structure and insight into their early development. We
continue the work of Harris et al. (2013), who identified a set of predictors that accurately determined the number of clusters Ngc, through analysis of an incomplete dataset.
We aimed to improve upon these results through imputation of the missing data. A
small amount of precision was gained for the slope of Ngc~ R_e*sigma_ e, while the intercept
suffered a small loss of precision. Estimates of intrinsic variance also increased with
the addition of imputed data.
We also found galaxy morphological type to be a significant predictor of Ngc in
a model with R_e*sigma_ e. Although it increased precision of the slope and reduced the
residual variance, its overall contribution was negligible. / Thesis / Master of Science (MSc)
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Improving the Local Distance Scale from Empirically Calibrated Stellar IsochronesAn, Deokkeun 11 September 2008 (has links)
No description available.
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A search for carbon and M-type stars in eight globular clusters /Palmer, Leon George January 1980 (has links)
No description available.
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The HST large programme on omega Centauri - I. Multiple stellar populations at the bottom of the main sequence probed in NIR-OpticalMilone, A. P., Marino, A. F., Bedin, L. R., Anderson, J., Apai, D., Bellini, A., Bergeron, P., Burgasser, A. J., Dotter, A., Rees, J. M. 07 1900 (has links)
As part of a large investigation with Hubble Space Telescope to study the faintest stars within the globular cluster omega Centauri, in this work we present early results on the multiplicity of its main sequence (MS) stars, based on deep optical and near-infrared observations. By using appropriate colour-magnitude diagrams, we have identified, for the first time, the two main stellar Populations I and II along the entire MS, from the turn-off towards the hydrogen-burning limit. We have compared the observations with suitable synthetic spectra of MS stars and conclude that the two main sequences (MSs) are consistent with stellar populations with different metallicity, helium and light-element abundance. Specifically, MS-I corresponds to a metal-poor stellar population ([Fe/H] similar to -1.7) with Y similar to 0.25 and [O/Fe] similar to 0.30. The MS-II hosts helium-rich (Y similar to 0.37-0.40) stars with metallicity ranging from [Fe/H] similar to -1.7 to -1.4. Below the MS knee (m(F160W) similar to 19.5), our photometry reveals that each of the two main MSs hosts stellar subpopulations with different oxygen abundances, with very O-poor stars ([O/Fe] similar to -0.5) populating the MS-II. Such a complexity has never been observed in previous studies of M-dwarfs in globular clusters. A few months before the launch of the James Webb Space Telescope, these results demonstrate the power of optical and near-infrared photometry in the study of multiple stellar populations in globular clusters.
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Stellar Mass and Population Diagnostics of Cluster GalaxiesROEDIGER, JOEL CHRISTOPHER 03 October 2013 (has links)
We conduct a broad investigation about stellar mass and population diagnostics in order to formulate novel constraints related to the formation and evolution of galaxies from a nearby cluster environment. Our work is powered by the use of stellar population models which transform galaxy colours and/or absorption line strengths into estimates of its stellar properties. As input to such models, we assemble an extensive compilation of age and chemical abundance information for Galactic globular clusters. This compilation allows a confident expansion of these models into new regions of parameter space that promise to refine our knowledge of galactic chemical evolution.
We then draw upon a state-of-the-art spectroscopic and photometric survey of the Virgo galaxy cluster in order to constrain spatial variations of the stellar ages, metallicities, and masses within its member galaxies, and their dynamical masses. We interpret these data in the context of the histories of star formation, chemical enrichment, and stellar mass assembly to formulate a broad picture of the build-up of this cluster’s content over time. In it, the giant early-type galaxies formed through highly dissipational processes at early times that built up most of their stellar mass and drew significant amounts of dark matter within their optical radii. Conversely, dwarf early-types experienced environmental processes that quenched their star formation during either the early stages of cluster assembly or upon infall at later times. Somewhat perplexing is our finding that the internal dynamics of these galaxies are largely explained by their stellar masses. Lastly, Virgo spirals also suffer from their dense environment, through ram pressure stripping and/or tidal harrassment. In addition to quenching, these effects leave an imprint on their internal dynamical evolution too. Late-type spirals exhibit evidence of having ejected significant amounts of baryons from their inner regions, likely via energetic feedback events.
Rich as our picture of the history of the Virgo cluster has become, real progress in our understanding of this system will truly benefit from future high-resolution cosmological and hydrodynamic simulations of this environment. Such simulations are still in their infancy, but the data assembled here should soon provide their most direct validation. / Thesis (Ph.D, Physics, Engineering Physics and Astronomy) -- Queen's University, 2013-09-30 23:32:48.575
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Homologous evolution in the post-collapse expansion of globular clustersApple, Rosemary K. January 2010 (has links)
We examine the evolution of globular star clusters, modelled as spherically symmetric stellar systems, using various techniques. Such clusters possess a central region of approximately uniform density which is referred to as the core. We concentrate our analysis on the evolution of the cluster after the core has undergone core collapse; a process where its radius decreases and its density increases. After this collapse, the system as a whole can expand in a self-similar fashion (homologous post-collapse evolution) which has long been thought to be due to gravitational interactions between different populations of single stars and binary stars in the core. We confirm this assumption by constructing a simple analytical model which combines much of the theoretical knowledge of previous research in the field. This model consists of two stellar populations, each defined by the mass of the individual stars, and a separate core. Our simple model is itself constructed from two simpler models – a twocomponent model without a core and a single mass model with a core – and takes into account the main gravitational interactions thought to drive the post-collapse evolution. To ensure that no important mechanisms have been neglected in our simple model, we will compare it with an N-body simulation. We compute our N-body models with NBODY6 (using a GPU version for large N). When we compare the N-body model with the simple model, we find qualitative agreement between them for most cases. Even though some mechanisms (e.g. escape of stars) are neglected in our simple model, we find that both models show homologous post-collapse evolution. We also review the homologous post-collapse Fokker-Planck model in the case of equal stellar masses derived by H´enon (1961) with the intention of extending this for the two-component case. We present our numerical solutions for H´enon’s model and find that our numerical solutions are in satisfactory agreement with the results shown in this paper. When we extend this work for a general two-component model (i.e. with no restriction on the number of heavier stars), we find that a homologous solution cannot be found with this approach. By contrast, we suggest that it would be possible to find a homologous two-component solution by extending the one-component solution published later by H´enon (1965), which differs from the earlier model by neglecting the external tidal field of the parent galaxy. Much of the work shown in this thesis would be relevant for such future study.
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Chemical tagging with APOGEE: discovery of a large population of N-rich stars in the inner GalaxySchiavon, Ricardo P., Zamora, Olga, Carrera, Ricardo, Lucatello, Sara, Robin, A. C., Ness, Melissa, Martell, Sarah L., Smith, Verne V., García-Hernández, D. A., Manchado, Arturo, Schönrich, Ralph, Bastian, Nate, Chiappini, Cristina, Shetrone, Matthew, Mackereth, J. Ted, Williams, Rob A., Mészáros, Szabolcs, Allende Prieto, Carlos, Anders, Friedrich, Bizyaev, Dmitry, Beers, Timothy C., Chojnowski, S. Drew, Cunha, Katia, Epstein, Courtney, Frinchaboy, Peter M., García Pérez, Ana E., Hearty, Fred R., Holtzman, Jon A., Johnson, Jennifer A., Kinemuchi, Karen, Majewski, Steven R., Muna, Demitri, Nidever, David L., Nguyen, Duy Cuong, O'Connell, Robert W., Oravetz, Daniel, Pan, Kaike, Pinsonneault, Marc, Schneider, Donald P., Schultheis, Matthias, Simmons, Audrey, Skrutskie, Michael F., Sobeck, Jennifer, Wilson, John C., Zasowski, Gail 11 February 2017 (has links)
Formation of globular clusters (GCs), the Galactic bulge, or galaxy bulges in general is an important unsolved problem in Galactic astronomy. Homogeneous infrared observations of large samples of stars belonging to GCs and the Galactic bulge field are one of the best ways to study these problems. We report the discovery by APOGEE (Apache Point Observatory Galactic Evolution Experiment) of a population of field stars in the inner Galaxy with abundances of N, C, and Al that are typically found in GC stars. The newly discovered stars have high [N/Fe], which is correlated with [Al/Fe] and anticorrelated with [C/Fe]. They are homogeneously distributed across, and kinematically indistinguishable from, other field stars within the same volume. Their metallicity distribution is seemingly unimodal, peaking at [Fe/H] similar to -1, thus being in disagreement with that of the Galactic GC system. Our results can be understood in terms of different scenarios. N-rich stars could be former members of dissolved GCs, in which case the mass in destroyed GCs exceeds that of the surviving GC system by a factor of similar to 8. In that scenario, the total mass contained in so-called 'first-generation' stars cannot be larger than that in 'second-generation' stars by more than a factor of similar to 9 and was certainly smaller. Conversely, our results may imply the absence of a mandatory genetic link between 'second-generation' stars and GCs. Last, but not least, N-rich stars could be the oldest stars in the Galaxy, the by-products of chemical enrichment by the first stellar generations formed in the heart of the Galaxy.
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NEUTRON STAR MASS–RADIUS CONSTRAINTS OF THE QUIESCENT LOW-MASS X-RAY BINARIES X7 AND X5 IN THE GLOBULAR CLUSTER 47 TUCBogdanov, Slavko, Heinke, Craig O., Özel, Feryal, Güver, Tolga 07 November 2016 (has links)
We present Chandra/ACIS-S subarray observations of the quiescent neutron star (NS) low-mass X-ray binaries X7 and X5 in the globular cluster 47 Tuc. The large reduction in photon pile-up compared to previous deep exposures enables a substantial improvement in the spectroscopic determination of the NS radius and mass of these NSs. Modeling the thermal emission from the NS surface with a non-magnetized hydrogen atmosphere and accounting for numerous sources of uncertainties, we obtain for the NS in X7 a radius of R = 11.1(-0.7)(+0.8) km for an assumed stellar mass of M = 1.4 M-circle dot (68% confidence level). We argue, based on astrophysical grounds, that the presence of a He atmosphere is unlikely for this source. Due to the excision of data affected by eclipses and variable absorption, the quiescent low-mass X-ray binary X5 provides less stringent constraints, leading to a radius of R = 9.6(-1.1)(+0.9) km, assuming a hydrogen atmosphere and a mass of M. =. 1.4 Me. When combined with all existing spectroscopic radius measurements from other quiescent low-mass X-ray binaries and Type I X-ray bursts, these measurements strongly favor radii in the 9.9-11.2 km range for a similar to 1.5 M-circle dot NS and point to a dense matter equation of state that is somewhat softer than the nucleonic ones that are consistent with laboratory experiments at low densities.
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Busca e análise de sistemas estelares do halo externo da galáxiaCanaza, Elmer Fidel Luque January 2014 (has links)
Uma previsão fundamental do cenário L cold dark matter (LCDM) na formação de estruturas é que os halos galácticos de DM do tamanho da Via Láctea (MW) crescem pela acreção de subsistemas menores. Neste contexto, simulações deNcorpos prevêem um número de sub-halos de matéria escura, cujo tamanho e massa são comparáveis às galáxias anãs, que é muito maior do que as galáxias satélites conhecidas. Este é o que se convencionu chamar de problema das satélites faltantes (MSP). A interpretação mais popular do MSP é que os sub-halos de matéria escura menores são extremamente ineficientes na formação de estrelas, o que torna mais difícil detectá-los. Com a chegada dos grandes levantamentos fotométricos, nos últimos anos, a descoberta de uma nova população de galáxias satélites que orbitam a MW fornece evidências empíricas para acreditar que realmente existem várias galáxias pouco luminosas não detectadas ou que simplesmente habitam regiões no céu que ainda não foram observadas. Neste trabalho implementamos um algoritmo estatístico eficiente para detectar subestruturas ultra fracas da MW. O código, chamado SPARSEX, foi testado e otimizado usando um conjunto de objetos estelares previamente identificados nos dados do Sloan Digital Sky Survey (SDSS), conseguindo recuperar todos os objetos com sucesso. Além disso, a aplicação do algoritmo aos dados dos dois primeiro anos do Dark Energy Survey (DES) deu como resultado centenas de candidatos a sistemas estelares. Dezessete sistemas estelares detectados em comum com outras técnicas de busca por subestruturas, implementadas dentro do grupo de colaboração do DES, foram publicados em três artigos em 2015. Um dos candidatos publicados é o aglomerado estelar DES 1. DES1 foi detectado pelo código SPARSEX com uma alta significância estatística e aparece nas imagens do DES como uma concentração compacta de fontes pontuais azuis. O sistema estelar é consistente com uma população velha e pobre em metal. Assumindo dois diferentes perfis de densidade, os quais permitem estimar a probabilidade de que cada estrela realmente pertença ao sistema, determinamos uma distância heliocêntrica e uma magnitude absoluta total num intervalo de 77.6—87.1 kpc e 3.00 . MV . 2.21, respectivamente. O raio à meia-luz desse objeto, rh 9.88 pc, e a luminosidade são consistentes com um aglomerado estelar de baixa luminosidade do halo externo. DES1 também é x alongado (e 0.6), o que faz supor que este objeto está em estágio avançado de dissolução. Mais tarde, através de uma cuidadosa reanálise de nossos resultados, dois novos candidatos foram detectados, DES J01111341 e DES J0225+0304. Os candidatos estão localizados a uma distância heliocêntrica de 25 kpc e parecem também estar dominados por populações estelares velhas e pobres em metais. Suas distâncias ao plano orbital da galáxia anã de Sagitário, 1.73 kpc (DES J01111341) e 0.50 kpc (DES J0225+0304), indicam que eles estão possivelmente associados com a corrente da anã de Sagitário. O raio à meia-luz (rh ' 4.55 pc) e a luminosidade (MV ' +0.3) de DES J01111341 são consistentes com um aglomerado estelar ultra fraco, enquanto o raio à meia-luz (rh ' 18.55 pc) e a luminosidade (MV ' 1.1) de DES J0225+0304 colocam este objeto em uma região ambígua do plano tamanho-luminosidade entre aglomerados estelares e galáxias anãs. Determinações dos parâmetros característicos da corrente de Sagitário, tais como o espalhamento de metalicidade (2.18 . [Fe/H] . 0.95) e o gradiente de distância (23 kpc . D . 29 kpc), dentro da área amostrada do DES no hemisfério sul, também indicam uma possível associação com estes sistemas. Se esses objetos forem confirmados através de follow-up espectroscópico como sistemas ligados gravitacionalmente e compartilharem uma trajetoria Galáctica com a corrente de Sagitário, DES J01111341 e DES J0225+0304 seriam os primeiros sistemas estelares ultra fracos associados com tal corrente. Recentemente, nós reportamos a descoberta de um novo aglomerado estelar, DES 3. O novo sistema foi detectado como uma sobredensidade estelar nos dados do primeiro ano do DES e confirmado com follow-up fotométrico obtido com o Southerm Astrophysical Research (SOAR) Telecope. Nós determinamos que DES 3 está localizado a uma distância heliocêntrica de 76 kpc e é dominado por uma população velha (' 9.8Ganos) e pobre em metal ([Fe/H] ' 1.88). Embora os valores de idade e metalicidade de DES 3 são semelhantes aos aglomerados globulares, o seu raio à meia-luz (rh 6.5 pc) e a luminosidade (MV 1.9) são mais indicativos de um aglomerados estelar fraco. Com base no tamanho angular aparente, o DES 3, com um valor de rh 0.03, está entre os menores aglomerados estelares fracos conhecidos até à data. Estas novas detecções indicam que o censo de satélites da MW é ainda incompleto. A identificação e estudo de novos satélites em futuros surveys, como por exemplo o Large Synoptic Survey Telescope (LSST) será crucial para a nossa compreensão das subestruturas existentes no halo Galáctico e a evolução da Galáxia como um todo. / A fundamental prediction of the L cold dark matter (LCDM) scenario of structure formation is that galactic DM haloes of the size of the Milky Way (MW) grow by the accretion of smaller sub-systems. In this context, Nbody simulations predict a number of dark matter subhalos, with size and mass comparable to dwarf galaxies, but which is much larger than currently known satellite galaxies. This is what is conventionally called the missing satellites problem (MSP). The most popular interpretation of the MSP is that the smaller dark matter subhalos are extremely inefficient in star formation, making it more difficult to detect them. With the arrival of large photometric surveys, in recent years, the discovery of a new population of satellite galaxies orbiting the MW provides empirical evidence to believe that there are actually several low luminosity galaxies that were not yet detected or that simply inhabit regions in the sky that have not yet been observed. In this work we present an efficient statistical algorithm to detect ultra-faint MW substructures. The code, called SPARSEX, was tested and optimized using a set of stellar objects previously identified in the Sloan Digital Sky Survey (SDSS) data. It has detected successfully all known objects. In addition, the algorithm was applied on the first two years of Dark Energy Survey (DES) data, resulting in hundreds of stellar system candidates. Seventeen stellar systems detected in common with other substructure search techniques implemented within the DES collaboration were published in three papers in 2015. In particular, one published candidate is a star cluster, DES 1. DES 1 was detected by the SPARSEX code with high statistical significance and appears in DES images as a compact concentration of blue point sources. The stellar system is consistent with being dominated by an old and metal-poor population. Assuming two different density profiles, based on which we may evaluate a membership probability for each star, we determined a heliocentric distance and total absolute magnitude in the ranges of 77.6—87.1 kpc and 3.00 . MV . 2.21, respectively. The half-light radius of this object, rh 9.88 pc, and luminosity are consistent with a low-mass halo star cluster. DES1 is also elongated (e 0.6), which suggests that this object is in advanced stage of dissolution. Later, through a careful reanalysis of our results, two new candidates were detected, DES J01111341 e DES J0225+0304. The candidates are located at a heliocentric xii distance of 25 kpc and appear to have old and metal-poor populations as well. Their distances to the Sagittarius dwarf orbital plane, 1.73 kpc (DES J01111341) and 0.50 kpc (DES J0225+0304), indicate that they are possibly associated with the Sagittarius dwarf stream. The half-light radius (rh ' 4.55 pc) and luminosity (MV ' +0.3) of DES J01111341 are consistent with it being an ultra-faint star cluster, while the half-light radius (rh ' 18.55 pc) and luminosity (MV ' 1.1) of DES J0225+0304 place it in an ambiguous region of size-luminosity space between star clusters and dwarf galaxies. Determinations of the characteristic parameters of the Sagittarius stream, such as its metallicity spread (2.18 . [Fe/H] . 0.95) and distance gradient (23 kpc . D . 29 kpc), within the DES footprint in the Southern hemisphere, also indicate a possible association with these systems. If theses objects are confirmed through spectroscopic follow-up to be gravitationally bound systems and to share a Galactic trajectory with the Sagittarius stream, DES J01111341 and DES J0225+0304 would be the first ultra-faint stellar systems associated with the Sagittarius stream. Recently, we reported the discovery of a new star cluster, DES 3. The new system was detected as a stellar overdensity in first-year DES data, and confirmed with deeper photometry from the Southern Astrophysical Research (SOAR) telescope. We determine that DES 3 is located at a heliocentric distance of 76 kpc and it is dominated by an old (' 9.8 Gyr) and metal-poor ([Fe/H] ' 1.88) population. While the age and metallicity values of DES 3 are similar to globular clusters, its half-light radius (rh 6.5 pc) and luminosity (MV 1.9) are more indicative of faint star clusters. Based on the apparent angular size, DES 3, with a value of rh 0.03, is among the smallest faint star clusters known to date. These new detections indicate that the MW satellites census is still incomplete. The identification and study of new satellites in future surveys, such as the Large Synoptic Survey Telescope (LSST), will be crucial to our understanding of substructures in the Galactic halo and the evolution of the Galaxy as a whole.
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