Global ETD Search

41	Pulsation Properties in Asymptotic Giant Branch Stars Norgren, Ofelia January 2019 (has links) Asymptotic Giant Branch (AGB) stars are stars with low- to intermediate mass in a late stage in their stellar evolution. An important feature of stellar evolution is the ongoing nucleosynthesis, the creation of heavier elements. Unlike main sequence stars, the AGB stars have a thick convective envelope which makes it possible to dredge-up the heavier fused elements from the stellar core to its surface. AGB stars are also pulsating variable stars, meaning the interior expands and contracts, causing the brightness to fluctuate. These pulsations will also play a major role in the mass loss observed in these stars. The mass loss is caused by stellar winds that accelerate gas and dust from the surface of these stars and thereby chemical enrich the interstellar medium. It is important to understand the properties of these pulsations since they play a key role in how stellar winds are produced and then enrich the galaxy with heavier synthesized elements. These pulsation periods can be observed with their corresponding Light-Curves, where the periodic motion of the brightness can be clearly seen. The main goal with this project is to calculate these pulsation periods for different AGB stars and compare these values with the periods listed in the General Catalogue of Variable Stars (GCVS). The comparison between these values gives a better understanding of methods of determining these periods and the uncertainties that follow. / Asymptotiska jättegrenen är en del av slutstadiet för låg- till medelmassiva stjärnor (AGB stjärnor). Ett viktigt kännetecken hos stjärnutvecklingen är den pågående nukleosyntesen, sammanslagningen av tyngre ämnen i stjärnans inre. Till skillnad mot stjärnor på huvudserien har AGB stjärnor ett tjockt konvektivt lager som gör det möjligt att dra upp dessa nybildade ämnen till stjärnans yta. AGB stjärnor är pulserande variabla stjärnor där variationer i stjärnans radie gör att ljusstyrkan varierar. Dessa pulsationer kommer även att spela en viktig roll för den massförlust som observeras hos dessa stjärnor. Massförlusten orsakas av stjärnvindar som accelererar gas och stoft från stjärnans yta och därmed kemiskt berikar det interstellära mediet. Det är viktigt att förstå dessa pulsationer eftersom de är en viktig komponent för hur stjärnvindar uppstår och sedan berikar galaxer med tyngre ämnen. Dessa pulsationsperioder kan studeras genom att observera stjärnornas ljuskurvor, där man tydligt ser det periodiska beteendet hos ljusstyrkan. Det huvudsakliga målet med detta projekt är att beräkna dessa perioder för olika AGB stjärnor och att sedan jämföra dem med värden från General Catalogue of Variable Stars (GCVS). Jämförelsen mellan dessa värden ger en bättre förståelse för metoderna som används för att bestämma dessa perioder och hur osäkra dessa värden är. Astronomy Asymptotic Giant Branch stars Stellar Evolution Variable Stars Power Spectrum Astronomy, Astrophysics and Cosmology Astronomi, astrofysik och kosmologi
42	Inverse Problems in Asteroseismology Bellinger, Earl Patrick 16 May 2018 (has links) No description available. 510 asteroseismology variable stars machine learning stellar evolution astrophysics stellar astrophysics stellar models inverse problems astroinformatics Informatik (PPN619939052)
43	Massive stars in the Galactic Center Quintuplet cluster Liermann, Adriane January 2009 (has links) The presented thesis describes the observations of the Galactic center Quintuplet cluster, the spectral analysis of the cluster Wolf-Rayet stars of the nitrogen sequence to determine their fundamental stellar parameters, and discusses the obtained results in a general context. The Quintuplet cluster was discovered in one of the first infrared surveys of the Galactic center region (Okuda et al. 1987, 1989) and was observed for this project with the ESO-VLT near-infrared integral field instrument SINFONI-SPIFFI. The subsequent data reduction was performed in parts with a self-written pipeline to obtain flux-calibrated spectra of all objects detected in the imaged field of view. First results of the observation were compiled and published in a spectral catalog of 160 flux-calibrated $K$-band spectra in the range of 1.95 to 2.45,$mu$m, containing 85 early-type (OB) stars, 62 late-type (KM) stars, and 13 Wolf-Rayet stars. About 100 of these stars are cataloged for the first time. The main part of the thesis project was concentrated on the analysis of the WR stars of the nitrogen sequence and one further identified emission line star (Of/WN) with tailored Potsdam Wolf-Rayet (PoWR) models for expanding atmospheres (Hamann et al. 1995) that are applied to derive the stellar parameters of these stars. For this purpose, the atomic input data of the PoWR models had to be extended by further line transitions in the near-infrared spectral range to enable adaequate model spectra to be calculated. These models were then fitted to the observed spectra, revealing typical paramters for this class of stars. A significant amount of hydrogen of up to $X_text{H} sim 0.2$ by mass fraction is still present in their stellar atmospheres. The stars are also found to be very luminous ($log{(L/L_odot)} > 6.0$) and show mass-loss rates and wind characteristics typical for radiation-driven winds. By comparison with stellar evolutionary models (Meynet & Maeder 2003a; Langer et al. 1994), the initial masses were estimated and indicate that the Quintuplet WN stars are descendants from the most massive O stars with $M_text{init} > 60 M_odot$ and their ages correspond to a cluster age of 3-5,million years. The analysis of the individual WN stars revealed an average extinction of $A_K =3.1 pm 0.5$,mag ($A_V = 27 pm 4$) towards the Quintuplet cluster. This extinction was applied to derive the stellar luminosities of the remaining early-type and late-type stars in the catalog and a Hertzsprung-Russell diagram could be compiled. Surprisingly, two stellar populations are found, a group of main sequence OB stars and a group of evolved late-type stars, i.e. red supergiants (RSG). The main sequence stars indicate a cluster age of 4 million years, which would be too young for red supergiants to be already present. A star formation event lasting for a few million years might possibly explain the Quintuplet's population and the cluster would still be considered coeval. However, the unexpected and simultaneous presence of red supergiants and Wolf-Rayet stars in the cluster points out that the details of star formation and cluster evolution are not yet well understood for the Quintuplet cluster. / Die vorgelegte Arbeit befasst sich mit der Spektralanalyse der massereichen Sterne, speziell der Wolf-Rayet Sterne der Stickstoffsequenz, des Quintuplet-Sternhaufens im Galaktischen Zentrum, welches durch Staubwolken vor visuellen Beobachtungen verborgen ist. Der Sternhaufen wurde in einer der ersten Infrarot-Durchmusterungen entdeckt (Okuda et al. 1987, 1989) und f"ur dieses Projekt mit dem Grossteleskop ESO-VLT und dem Infrarotinstrument SINFONI-SPIFFI beobachtet. Die Daten wurden aufbereitet und die flusskalibrierten Spektren in einem Katalog ver"offentlicht. Darin enthalten sind 85 Sterne fr"uhen Spektraltyps (O- und B-Sterne), 62 Sterne sp"aten Spektraltyps (K- und M-Sterne), sowie 13 Wolf-Rayet Sterne. Etwa 100 Sterne sind zum ersten mal detektiert und katalogisiert worden. Die flusskalibrierten Spektren der Wolf-Rayet Sterne der Stickstoffsequenz (WN) wurden mit den Potsdam Wolf-Rayet Modellen f"ur expandierende Sternatmosph"aren (Hamann et al. 1995) untersucht, wozu zun"achst Atomdaten der Modelle f"ur den Infrarotbereich erg"anzt werden mussten. Verschiedene Modellspektren und -energieverteilungen wurden mit den Beobachtungen verglichen, um die Sternparameter Temperatur, Radius, Leuchtkraft und die Charakteristik des Sternwinds Geschwindigkeit, chemische Zusammensetzung und Massenverlustrate zu bestimmen. Der ermittelte hohe Wasserstoffgehalt der Winde der WN-Sterne zeigt, dass sie Abk"ommlinge von massereichen O-Sternen sind, die die Hauptreihe verlassen haben. Desweiteren sind die Sterne sehr leuchtkr"aftig ($log(L/L_odot) > 6$) und zeigen Massenverlustraten, die typisch sind f"ur strahlungsgetriebenen Sternwinde. Im Vergleich mit Sternentwicklungsmodellen (Meynet & Maeder 2003a; Langer et al. 1994) ergeben sich Anfangsmassen von $M_text{init}>60,M_odot$, sowie ungef"ahre Sternalter von 3-5 Millionen Jahren f"ur die WN-Sterne, was dem angenommenen Altern des Quintuplet-Haufens entspricht. Durch die Analyse der spektralen Energieverteilungen der einzelnen WN-Sterne konnte eine mittlere interstellare Extinktion von $A_K =3.1 pm 0.5$,mag ($A_V = 27 pm 4$,mag) in der Richtung des Quintuplet-Haufens ermittelt und f"ur die Bestimmung der Leuchtkr"afte der verbleibenden Sterne des Katalog verwendet werden. Die anschliess ende vorl"aufige Analyse ergab eine Dichotomie der Sternpopulation von fr"uhen und sp"aten Sternen im Hertzsprung-Russell-Diagramm. W"ahrend die OB-Sterne entsprechend der Entwicklungstheorie auf der Hauptreihe des Haufens liegen, befinden sich die KM-Sterne im entwickelten Stadium der Roten Riesen, welches f"ur Sterne diesen Typs fr"uhestens nach 7 Millionen Jahren erwartet wird. Somit steht die zeitgleiche Entstehung aller Sterne des Sternhaufens in Frage. Sie wird im Rahmen von Haufenzugeh"origkeit und einer Phase ausgedehnter Sternentstehung diskutiert. Es bleibt anzuerkennen, dass die Sternentstehung und -entwicklung auch im speziellen Fall des Quintuplet-Haufens noch nicht hinreichend gut verstanden sind. Galaktisches Zentrum massereiche Sterne Sternatmosphären Sternentwicklung Galactic center Quintuplet cluster massive stars stellar atmospheres stellar evolution Astronomy and allied sciences
44	Evolution of low and intermediate mass stars in binary systems: a new look at Algol systems Deschamps, Romain 03 June 2015 (has links) Despite being observed since the XVIIIth century, Algol systems and related objects are<p>still rather poorly understood. We know that they are composed by a generally B-A main sequence<p>star and a lighter but more evolved companion star. This paradox is explained by the transfer of mass<p>between the two stars, but new problems arose. In particular, I studied the mass-transfer driven spin-<p>up of the accreting star that drives the star to critical rotation and the puzzling, indirectly observed, non-conservative evolution. / Doctorat en Sciences / info:eu-repo/semantics/nonPublished Physique Astrophysics Double stars Variable stars Stars -- Evolution Astrophysique Etoiles doubles Etoiles variables Etoiles -- Evolution Algol binary stars Stellar evolution
45	Étude de l'influence de la perte de masse sur l'évolution des anomalies d'abondance dans plusieurs types d'étoiles / A Study of the Effects of Mass Loss on the Evolution of Abundance Anomalies in Many Types of Stars Vick, Mathieu 15 October 2010 (has links) La diffusion atomique joue un rôle déterminant dans l'évolution d'étoiles de plusieurs types (Michaud 1970). Dans ces étoiles, la diffusion atomique est principalement régie par la compétition entre l'accélération gravitationnelle et les accélérations radiatives et peut par ce biais mener à de fortes anomalies d'abondances. À l'aide d'un modèle évolutif qui considère les accélérations radiatives de 28 espèces, il est possible de modéliser plusieurs types d'étoiles de Population I, incluant le Soleil (Turcotte et al. 1998a), les étoiles de type F (Turcotte et al. 1998b), les étoiles AmFm (Richer et al. 2000; Richard et al. 2001) et les étoiles de métallicité solaire ayant une masse entre 0.5 et 1.4 Msol (Michaud et al. 2004), ainsi que des étoiles de Pop II (Michaud et al. 2005). Cependant, les modèles qui ne considèrent que la diffusion atomique comme processus de transport dans les intérieurs stellaires génèrent des anomalies d'abondance plus grandes que celles observées pour les étoiles de type Am, Ap et HgMn. Dans ces étoiles, il y a donc un ou plusieurs autres processus qui peuvent influencer le transport de particules, tels la circulation méridionale, la turbulence et la perte de masse. L'objet de cet thèse est de contraindre l'importance de la perte de masse dans l'intérieur de plusieurs étoiles chimiquement particulières de Pop I et Pop II, tout en essayant de différencier ces effets par rapport à ceux reliés aux processus de mélange turbulents. / Atomic diffusion plays an important role in the evolution of many types of stars (Michaud 1970). In these stars, elemental migration is modulated by the competition between radiative accelerations and gravity, and can thus lead to important abundance anomalies both in the interior and at the surface of these stars. With a stellar evolution model which considers detailed particle transport with radiative accelerations for 28 elements, one can study the evolution of many types of stars of Pop II including the Sun (Turcotte et al. 1998a), F stars (Turcotte et al. 1998b), AmFm stars (Richer et al. 2000; Richard et al. 2001), as well as less massive stars (0.5 to 1.4 Msol) with solar metallicity (Michaud et al. 2004). Furthermore, such a model can also look into the evolution of Pop II chemically peculiar stars (Michaud et al. 2005). However, models which consider atomic diffusion as the sole process affecting particle transport lead to abundance anomalies which are greater than the ones observed. There is thus at least one macroscopic process which is preventing such large anomalies to appear at the surface. These processes include mass loss, meridional circulation and turbulence. The main goal of this thesis is to constrain the relative importance of mass loss in the interiors of many chemically peculiar stars of Pop I and Pop II, as well as to properly differentiate its effects from those generated by turbulent mixing processes. Évolution stellaire Diffusion atomique Perte de masse Anomalies d'abondance Étoiles chimiquement particulières Stellar evolution Atomic diffusion Mass loss Abundance anomalies Chemically peculiar stars
46	Dwarf and Subgiant Stars as Probes of Galactic Chemical and Dynamical Evolution Thorén, Patrik January 2001 (has links) Stellar chemical abundances provide astronomers with vital information about the production of chemical elements. Some stars preserve the composition of the environment in which they were born on their surfaces. By analysing the light from a star, the abundances of elements, its age and its path in space can be derived, and translated into the language of galactic history. The spallative history of boron in the early Galaxy was reinvestigated by observations of an ultraviolet spectral line in the old star HD 140283 with the Hubble Space Telescope. The line was barely detected and the upper limit abundance derived was lower than expected, which calls for further observations of this line in halo stars. Stars evolved into subgiants were observed with the ESO CAT, La Silla, and NOT, La Palma, to deduce their usefulness for galactic evolution studies. The high resolution spectroscopy study of the 26 objects showed that these stars are indeed useful for such studies. They are more luminous than dwarf stars and their ages can be accurately derived. They do not seem to have changed their surface abundances due to their evolution into giants. Subgiants can successfully be used to observationally reach regions further from the Earth, which can remove local biases that may appear when only observing nearby dwarf stars. A NLTE investigation of neutral Ca showed that cool metal rich dwarf stars did not deviate significantly from LTE, as had earlier been suggested. By an LTE analysis of a sample of 17 such dwarfs, using recent MARCS atmospheres, synthetic spectroscopy and modern atomic line data, cool metal rich dwarfs were shown not to deviate significantly from the expected abundance patterns in a number of elements. This increases the number of potential targets for studies of galactic chemical evolution in the metal rich regime since most stars are cool. Astronomy Abundances atomic data Galactic evolution late-type stars main sequence stars subgiants Pop II Pop I stellar evolution Astronomi Astronomy and astrophysics Astronomi och astrofysik
47	On the Winds of Carbon Stars and the Origin of Carbon : A Theoretical Study Mattsson, Lars January 2009 (has links) Carbon is the basis for life, as we know it, but its origin is still largely unclear. Carbon-rich Asymptotic Giant Branch (AGB) stars (carbon stars) play an important rôle in the cosmic matter cycle and may contribute most of the carbon in the Galaxy. In this thesis it is explored how the dust-driven mass loss of these stars depends on the basic stellar parameters by computing a large grid of wind models. The existence of a critical wind regime and mass-loss thresholds for dust-driven winds are confirmed. Furthermore, a steep dependence of mass loss on carbon excess is found. Exploratory work on the effects of different stellar metallicities and the sizes of dust grains shows that strong dust-driven winds develop also at moderately low metallicities, and that typical sizes of dust grains affect the wind properties near a mass-loss threshold. It is demonstrated that the mass-loss rates obtained with the wind models have dramatic consequences when used in models of carbon-star evolution. A pronounced superwind develops soon after the star becomes carbon rich, and it therefore experiences only a few thermal pulses as a carbon star before the envelope is lost. The number of dredge-up events and the thermal pulses is limited by a self-regulating mechanism: each thermal pulse dredges up carbon, which increases the carbon excess and hence also the mass-loss rate. In turn, this limits the number of thermal pulses. The mass-loss evolution during a thermal pulse (He-shell flash) is considered as an explanation of the observations of so-called detached shells around carbon stars. By combining models of dust-driven winds with a stellar evolution model, and a simple hydrodynamic model of the circumstellar envelope, it is shown that wind properties change character during a He-shell flash such that a thin detached gas shell can form by wind-wind interaction. Finally, it is suggested that carbon stars are responsible for much of the carbon in the interstellar medium, but a scenario where high-mass stars are major carbon producers cannot be excluded. In either case, however, the carbon abundances of the outer Galactic disc are relatively low, and most of the carbon has been released quite recently. Thus, there may neither be enough carbon, nor enough time, for more advanced carbon-based life to emerge in the outer Galaxy. This lends some support to the idea that only the mid-part of the Galactic disc can be a “Galactic habitable zone”, since the inner parts of the Galaxy are plagued by frequent supernova events that are presumably harmful to all forms of life. AGB stars carbon stars mass loss stellar winds circumstellar matter cosmic dust stellar evolution nucleosynthesis galactic chemical evolution Astronomy and astrophysics Astronomi och astrofysik
48	Vliv ztráty hmoty hvězd na dynamiku hvězdokup / The influence of the stellar mass-loss on the dynamics of star clusters Dinnbier, František January 2012 (has links) This work aims at studying the influence of the stellar mass-loss, resulting from the stellar evolution, on the dynamics of massive star clusters. The emphasis has been put on the mass-loss by low-mass and intermediate-mass stars (m < 8 Mo) that form, at the end of their life, a planetary nebula. The expansion speed of gas released by these stars is lower than the escape speed from sufficiently massive star clusters, and the gas can be retained by the cluster. For modelling of the gas hydrodynamics, a simple sticky-particles method was used. To carry out simulations in which gaseous and stellar particles mutually interact through their gravity, substantial modifications had to be realized in the N-body codes Nbody6 and Hermit. For the sake of comparing the influence of stellar mass-loss and relaxation processes, which are happening in the simplified model, two types of simulations were performed: one with the formation of gaseous particles and the other consisting of purely stellar component. The simulations in which the gas component was present showed out a significantly different evolution in the central part of the cluster than those in which the presence of gas was not considered.
49	Searches for Particle Dark Matter : Dark stars, dark galaxies, dark halos and global supersymmetric fits Scott, Pat January 2010 (has links) The identity of dark matter is one of the key outstanding problems in both particle and astrophysics. In this thesis, I describe a number of complementary searches for particle dark matter. I discuss how the impact of dark matter on stars can constrain its interaction with nuclei, focussing on main sequence stars close to the Galactic Centre, and on the first stars as seen through the upcoming James Webb Space Telescope. The mass and annihilation cross-section of dark matter particles can be probed with searches for gamma rays produced in astronomical targets. Dwarf galaxies and ultracompact, primordially-produced dark matter minihalos turn out to be especially promising in this respect. I illustrate how the results of these searches can be combined with constraints from accelerators and cosmology to produce a single global fit to all available data. Global fits in supersymmetry turn out to be quite technically demanding, even with the simplest predictive models and the addition of complementary data from a bevy of astronomical and terrestrial experiments; I show how genetic algorithms can help in overcoming these challenges. / At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 5: Accepted. Paper 6: Submitted. dark matter supersymmetry gamma rays dwarf galaxies stellar evolution cosmological perturbations phase transitions statistical techniques Astroparticle physics Astropartikelfysik Astroparticle physics Astropartikelfysik Cosmology Kosmologi Elementary particle physics Elementarpartikelfysik Computational physics Beräkningsfysik Formation and development of stars Stjärnors bildning och utveckling High energy astrophysics Högenergiastrofysik
50	A search for pulsating B-type variable stars in the southern open clusters NGC 6204 and Hogg 22 / Jacobus Johannes (Jaco) Mentz Mentz, Jacobus Johannes January 2013 (has links) The theory of stellar evolution and stellar structure relies on the observation of stars in di erent phases of their evolutionary cycle. The relation between observations and theory can be strengthened by obtaining observational data of a large sample of stars in a particular evolutionary phase. The search for Cephei stars, as conducted in this study, can contribute to the sample of known Cephei stars, where these interesting stars are massive non-supergiant early B-type stars, displaying pulsating behaviour which is not well understood. Stars tend to form in clusters where it can therefore be expected that young massive stars can be found in open clusters. For this reason two young southern open clusters were observed in order to search for B-type pulsating stars. The region of NGC 6204 and Hogg 22 was observed over a period of thirteen nights in Johnson B, V and I bands. NGC 6204 is believed to be the oldest cluster of the two at a distance of 0.8 kpc while the much younger Hogg 22 is more distant at 2.8 kpc. These two open clusters are located 6 arcminutes apart which made it possible to observe them simultaneously with a 12.8 12.8 arcminute eld of view. The observations were done with the newly installed 1600 telescope of the North-West University, South Africa. In order to do a variability search, periodic stars need to be identi ed from the cluster data, where a typical data set may contain thousands of scienti c images. In addition to the main motivation for this study, a pipeline was created in order to automate the photometry and data reduction processes. A Lomb-Scargle transform was applied to the stellar light curves in order to identify periodic sources. 354 signi cantly periodic stars were identi ed from the 3182 observed stars. Amongst them, two new possible Cephei stars were found together with a possible slowly pulsating B star (SPB), and numerous eclipsing binary systems. By using photometry of this region obtained by Forbes & Short (1996), instrumental magnitudes were transformed to a standard system in order to compare photometry results. From the constructed colour magnitude diagram of the two clusters, it could be seen that some stars, indicated by Forbes & Short (1996) to be cluster members, were in fact eld stars belonging to neither cluster. The reduction and photometry pipeline was implemented successfully on the data set, which also highlighted the importance of instrumentation and correct data analysis procedures. Possible improvements were identi ed in order to overcome di culties experienced during this study. / Thesis (MSc (Space Physics))--North-West University, Potchefstroom Campus, 2013 Stellar evolution Stellar structure Evolutionary cycle Cephei stars Pulsating stars Open star clusters Photometry Lomb-Scargle transform Light curves Slowly pulsating B stars Eclipsing binary systems Colour magnitude diagram Fi eld stars

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