Global ETD Search

91	Equilibre magnétohydrodynamique des protubérances solaires Malherbe, Jean-Marie 15 April 1983 (has links) (PDF) Observations et modelisation de l'équilibre magnéto hydro dynamique des protubérances solaires Soleil protubérances MHD
92	Inspection and Characterization of Exoplanet Using the CHARA Array Baines, Ellyn K 07 August 2007 (has links) Until the last decade or so, our entire knowledge of planets around Sun-like stars consisted of those in our own Solar System. This is no longer the case. Over 200 planets have been discovered through radial velocity surveys and photometric studies, both of which depend on observing the planet's effects on its host star. Much of our knowledge of the planets orbiting these stars is uncertain, based on assumptions about the stars' masses and the planets' orbital inclinations. This dissertation is comprised of two main sections. The first involves measuring the angular diameters for a sample of exoplanet host stars using Georgia State University's CHARA Array in order to learn more about the nature of these stars. These direct angular measurements are not dependent on the exoplanet systems' inclinations or the masses of the stars. Improved angular diameters lead to linear diameters when combined with HIPPARCOS parallax measurements, which in turn tell us of the stars' ages and masses. Of the 82 exoplanet systems observable with the CHARA Array, 31 host stars were observed and stellar angular diameters were measured for 26 systems. In the special case of an exoplanet system with a transiting planet, this direct measurement of the star's angular diameter leads to a direct measurement of the planet's diameter, when the planet-to-star-radii ratio is known from photometric studies. This was done for HD 189733. The star's angular diameter is 0.377 +/- 0.024 mas, which produces a stellar linear radius of 0.779 +/- 0.052 R_Sun and a planetary diameter of 1.19 +/- 0.08 R_Jupiter. The second part of this project involved the inspection of the exoplanet systems for stellar companions masquerading as planets. From radial velocity studies alone, it is impossible to distinguish between a planet in a high-inclination orbit and a low-mass stellar companion in a low-inclination orbit. Using the CHARA Array, it was possible to rule out certain secondary spectral types for each exoplanet system observed by studying the errors in the diameter fit and searching for separated fringe packets. While no definitive stellar companions were found, two expolanet systems, upsilon Andromedae and rho Coronae Borealis, exhibited behavior that were not consistent with the host star being a simple limb-darkened disk. stellar companions stellar diameters exoplanet systems optical/infrared interferometry Astrophysics and Astronomy Physics
93	Sizing Up the Stars Boyajian, Tabetha Suzanne 17 July 2009 (has links) For the main part of this dissertation, I have executed a survey of nearby, main sequence A, F, and G-type stars with the CHARA Array, successfully measuring the angular diameters of forty-four stars to better than 4% accuracy. The results of these observations also yield empirical determinations of stellar linear radii and effective temperatures for the stars observed. In addition, these CHARA-determined temperatures, radii, and luminosities are fit to Yonsei-Yale isochrones to constrain the masses and ages of the stars. These quantities are compared to the results found in Allende Prieto & Lambert (1999), Holmberg et al. (2007), and Takeda (2007), who indirectly determine these same properties by fitting models to observed photometry. I find that for most cases, the models underestimate the radius of the star by ~12%, while in turn they overestimate the effective temperature by ~ 1.5 - 4%, when compared to my directly measured values, with no apparent correlation to the star's metallicity or color index. These overestimated temperatures and underestimated radii in these works appear to cause an additional offset in the star's surface gravity measurements, which consequently yield higher masses and younger ages, in particular for stars with masses greater than ~ 1.3 M_sol. Alternatively, these quantities I measure are also compared to direct measurements from a large sample of eclipsing binary stars in Andersen (1991), and excellent agreement is seen within both data sets. Finally, a multi-parameter solution is found to fit color-temperature-metallicity values of the stars in this sample to provide a new calibration of the effective temperature scale for these types of stars. Published work in the field of stellar interferometry and optical spectroscopy of early-type stars are presented in Appendix D and E, respectively. Interferometry Infrared Stellar Astronomy Fundamental Properties Effective Temperatures Stellar Radii Astrophysics and Astronomy Physics
94	Measuring the Effective Wavelength of CHARA Classic Bowsher, Emily Collins 22 April 2010 (has links) This thesis presents an engineering project measuring the effective wavelength of the CHARA Classic beam combiner on the CHARA Array. Knowing the actual effective wavelength of light observed is very important because that value is necessary for determining astrophysical parameters of stars. Currently, the value used for CHARA Classic data comes from a model of the system and is based on numbers published by the manufacturer of the filter; it is not derived from measurements done on the system directly. We use two data collection methods to observe standard stars of different spectral types and calculate the wavelength of light recorded by the instrument for each star. We find the best estimate of the effective wavelength for the CHARA Classic K′-band configuration to be 2.138±0.003μm, a 0.56% decrease from the previously adopted value of 2.150μm. Our result establishes the first estimate of the uncertainty in the effective wavelength. Astronomical instrumentation Effective wavelength Long baseline interferometry CHARA Stellar diameters Stellar properties Astrophysics and Astronomy Physics
95	Superluminous supernovae : theory and observations Chatzopoulos, Emmanouil 25 October 2013 (has links) The discovery of superluminous supernovae in the past decade challenged our understanding of explosive stellar death. Subsequent extensive observations of superluminous supernova light curves and spectra has provided some insight for the nature of these events. We present observations of one of the most luminous self-interacting supernovae ever observed, the hydrogen-rich SN 2008am discovered by the Robotic Optical Transient Search Experiment Supernova Verification Project with the ROTSE-IIIb telescope located in the McDonald Observatory. We provide theoretical modeling of superluminous supernova light curves and fit the models to a number of observed events and similar transients in order to understand the mechanism that is responsible for the vast amounts of energy emitted by these explosions. The models we investigate include deposition of energy due to the radioactive decays of massive amounts of nickel-56, interaction of supernova ejecta with a dense circumstellar medium and magnetar spin-down. To probe the nature of superluminous supernovae progenitor stars we study the evolution of massive stars, including important effects such as rotation and magnetic fields, and perform multi-dimensional hydrodynamics simulations of the resulting explosions. The effects of rotational mixing are also studied in solar-type secondary stars in cataclysmic variable binary star systems in order to provide an explanation for some carbon-depleted examples of this class. We find that most superluminous supernovae can be explained by violent interaction of the SN ejecta with >1 Msun dense circumstellar shells ejected by the progenitor stars in the decades preceding the SN explosion. / text Supernovae Stellar evolution Massive stars Circumstellar matter Light curve Stellar rotation Hydrodynamics
96	Characterizing the Nearest Young Moving Groups McCarthy, Kyle 01 January 2015 (has links) Moving groups are associations of stars which originated from the same star forming region. These groups are typically young (< 200 Myr) since they have not dissipated into the galactic field population. Over the last 15 years, roughly 10 such moving groups have been found with distances < 150 pc (7 with distances < 100 pc), each with a unique velocity and position. This work first investigates the likelihood to resolve star from two moving groups (AB Doradus and Beta Pictoris) using high spacial resolution optical interferrometry and found 5 AB Doradus stars and 1 Beta Pictoris star with declinations > -30 could be spacially resolved. To more deeply characterize individual groups, we used the 2.7m telescope at the McDonald Observatory to observe 10 proposed AB Doradus stars and 5 proposed Octans-Near stars (3 probable members, 2 possible) with high resolution (R ~60,000) optical spectroscopy. Each group is characterized in three ways: (1) Chemical analysis to determine the homogeneity among members, (2) Kinematic traceback to determine the origin, and (3) Isochrone fitting to determine the age. We find the 8 stars in our AB Doradus sample are chemically homogeneous with [M/H] = -0.03 ± 0.06 dex, traceback to an age of 125 Myr, and the stars in this mass range are on the main sequence. The two deviants are a metal rich, potentially younger member and a metal poor, young star likely not associated with AB Doradus. In our Octans-Near sample, we find the 3 probable members have [M/H] = -0.06 ± 0.11, the stars do not trace back to a common origin, and the probable members are on the main sequence. In addition to these tests, we found that the probable members are slightly more lithium depleted than the Pleiades, implying an age between 125 and 200 Myr. Finally, we investigate systematic trends in fundamental stellar parameters from the use of different techniques. Preliminary results find differences in temperatures between interferrometric and spectroscopic techniques to be a function of temperature with a interferrometric temperatures being cooler by an average of 36 ± 115 K. We also calculated the chemical abundances as a function of condensation temperature for our moving group sample and predict 2 stars in AB Doradus could represent the initial star forming environment and discuss the implications for planet hosting stars in nearby moving groups. This updated characterization technique allows for a deeper understanding of the moving group environment. As future, high precision instruments emerge in astronomy (Jame Webb Space Telescope, GAIA, 30m class telescopes), moving groups are ideal targets since these associations will help us understand star forming regions, stellar evolution at young ages, constrain stellar evolutionary models, and identify planetary formation and evolution mechanisms. Pre-Main Sequence Stars Stellar Associations Optical Spectroscopy Fundamental Stellar Parameters
97	Observations and radiative hydrodynamic simulations of solar and stellar flares / Allred, Joel C., January 2005 (has links) Thesis (Ph. D.)--University of Washington, 2005. / Vita. Includes bibliographical references (p. 101-105).
98	Importance de la diffusion atomique et de ses conséquences hydrodynamiques sur la structure interne et les paramètres observationnels des étoiles / Importance of atomic diffusion and of its hydrodynamic consequences on internal structure and observational parameters of stars Deal, Morgan 20 September 2016 (has links) La diffusion atomique doit être prise en compte dans les modèles d'évolution stellaire car il s'agit d'une conséquence directe du fait que les étoiles sont des sphères auto-gravitantes composées d'un mélange de différents gaz (les éléments chimiques). L'équilibre des étoiles conduit à des gradients internes de pression, de densité et de température ainsi qu'à un transfert radiatif, l'ensemble produisant un effet sélectif sur les éléments (dans la plupart des cas dominé par la compétition entre le triage gravitationnel et les accélérations radiatives).Les interactions entre la diffusion atomique et les processus hydrodynamiques tels que la convection dynamique et la perte de masse sont étudiées depuis longtemps. Un processus important a cependant été oublié dans les modèles. Il s'agit de la convection double diffusive (ou thermohaline) induite par un gradient de μ instable, qui peut être produite par une accumulation locale d'éléments lourds à l'intérieur des étoiles due aux accélérations radiatives. Contrairement aux autres processus de mélange, il s'agit d'une conséquence directe de la diffusion atomique. Un effet similaire se produit à la base de la zone convective de surface en cas d'accrétion d’éléments lourds à la surface de l'étoile.Nous avons étudié la convection thermohaline induite par l'accrétion dans le cas du système 16 Cygni et les propriétés de ces deux étoiles avec le code TGEC. Nous avons inclus la prescription de Brown et al. 2013 pour la convection thermohaline. Nous avons ensuite calculé les fréquences d'oscillations de ces modèles à l'aide du code PULSE pour les comparer aux fréquences observées par Kepler. A partir de ces modèles, nous avons pu montrer qu'en accrétant 2/3 de la masse terrestre au début de la séquence principale (sur le modèle 16 Cyg B), la convection thermohaline induite par l'accrétion mélangeait l'étoile suffisamment profondément pour atteindre la zone de destruction du lithium et ainsi obtenir des abondances de lithium cohérentes avec les observations de 16 Cyg A et B.Nous avons étudié l'accumulation d’éléments lourds et l'effet de la convection thermohaline dans le cas des étoiles de type A. Dans ces étoiles, des abondances "particulières" (par rapport au soleil) ont été observées. Ceci est dû aux effets de la diffusion atomique qui sont très importants dans ces étoiles. Cependant, la diffusion atomique seule produit des variations d'abondances trop importantes et un moyen de reproduire les observations est de mélanger l'étoile assez profondément. Nous avons ensuite calculé des modèles incluant la diffusion atomique et la convection thermohaline en utilisant le code TGEC. Nous avons montré que ce processus pouvait modifier la structure interne de ces étoiles, et aussi les abondances de surface. Nous avons aussi inclus la convection thermohaline et l'accrétion dans le code de Montréal/Montpellier. Nous avons modifié plusieurs parties de ce code afin de pouvoir faire des comparaisons avec le TGEC pour comparer les résultats. Les résultats obtenus sont très similaires.Nous avons aussi déterminé les paramètres de l'étoile 94 Ceti à partir d'observations obtenues avec un instrument au sol. Cette étoile à une masse de 1.44 MΘ et est une bonne cible pour étudier l'effet des accélérations radiatives (qui ont un effet non négligeable pour des masses supérieures à 1.2 MΘ). Nous avons aussi comparé des modèles incluant des atmosphères complets afin d'en déterminer l'impact sur les fréquences.Nous avons travaillé sur les étoiles du halo pauvres en métaux pour lesquelles est observé une dispersion inexpliquée des abondances de lithium pour les métallicité très faible. Nous avons étudié la possibilité d'une accrétion sur ces étoiles qui pourrait produire de la convection thermohaline et détruire du lithium. / Atomic diffusion must be taken into account in the computations of stellar structure and evolution as it is a direct consequence of the fact that stars are self-gravitating spheres composed of a mixture of different gases (the chemical elements). The stellar equilibrium leads to internal gradients of pressure, density and temperature as well as an upward radiative transfer which produces a selective effect on the elements (in most cases dominated by the competition between gravitational settling and radiative acceleration).The interactions between atomic diffusion and well-known hydrodynamical processes like dynamical convection and mass loss have been studied for a long time. An important process was however forgotten in these computations. This is the double-diffusive (or fingering or thermohaline) convection induced by unstable μ-gradients, which can be produced by the local accumulation of heavy elements inside stars due to radiative acceleration. Contrary to the other hydrodynamical processes, fingering convection is not arbitrarily added in the computations. It is directly induced by atomic diffusion itself and cannot be avoided. It is thus very important to add this hydrodynamical process in stellar evolution modelling, which has never been done before our work. A similar effect occurs below the convective zone in case of accretion of heavy matter onto a star.We studied the accretion-induced fingering convection in the case of the stellar system 16 Cygni. We studied the properties of these two stars by computing models with the Toulouse Geneva Evolution Code (TGEC). We included the Brown et al. 2013 prescription for the computations of fingering convection in the code. We computed oscillation frequencies of these models using the PULSE code to compare it with Kepler observations. We found that if 2/3 of Earth mass is accreted at the beginning of the main sequence (on 16 Cyg B model), the accretion-induced fingering convection mixes the star deep enough to destroy the lithium and obtain the observed difference between 16 Cyg A and B.We studied the heavy element accumulation and the induced fingering convection in the case of Am stars. In these stars, peculiar surface abundances are observed (compared to the sun). This peculiarity is related to the effect of atomic diffusion, very important in these types of stars. However, atomic diffusion alone leads to abundance variations which are too large and one way to reproduce the observed abundance quantitatively is to assume mixing deep enough inside the star. We computed models including atomic diffusion (with radiative acceleration) and fingering convection with this prescription using the TGEC code. We find than this process may change the internal structure of the stars, and also the surface abundances. We also included fingering convection and the accretion process in the Montreal/Montpellier code. We modified some parts of this code (e.g. turbulence profiles) to compare the results obtained with the two codes. We computed some models and I found that the results are quite similar.We determined the stellar parameters of the star 94 Ceti (by using similar seismic computations as for 16 Cyg A and B) using ground-based observations. This star has a mass of 1.44 MΘ and is a good target to study the effect of radiative accelerations (which occur for masses larger than 1.2-1.3 MΘ). We also compared models with full atmosphere with the observations to determine the impact on oscillation frequencies.We worked on metal poor halo stars for which a dispersion of lithium surface abundance is observed for very small metallicities. We studied the possibility of an accretion of matter that can trigger fingering convection and destroy lithium. Abondances Diffusion Evolution stellaire Processus de transport Structure interne Abundances Diffusion Stellar evolution Transport processes Stellar structure
99	Clustering of Stars in Nearby Galaxies: Probing the Range of Stellar Structures January 2011 (has links) abstract: Most stars form in groups, and these clusters are themselves nestled within larger associations and stellar complexes. It is not yet clear, however, whether stars cluster on preferred size scales within galaxies, or if stellar groupings have a continuous size distribution. I have developed two methods to select stellar groupings across a wide range of size-scales in order to assess trends in the size distribution and other basic properties of stellar groupings. The first method uses visual inspection of color-magnitude and color-color diagrams of clustered stars to assess whether the compact sources within the potential association are coeval, and thus likely to be born from the same parentmolecular cloud. This method was developed using the stellar associations in the M51/NGC 5195 interacting galaxy system. This process is highly effective at selecting single-aged stellar associations, but in order to assess properties of stellar clustering in a larger sample of nearby galaxies, an automated method for selecting stellar groupings is needed. I have developed an automated stellar grouping selection method that is sensitive to stellar clustering on all size scales. Using the Source Extractor software package on Gaussian-blurred images of NGC 4214, and the annular surface brightness to determine the characteristic size of each cluster/association, I eliminate much of the size and density biases intrinsic to other methods. This automated method was tested in the nearby dwarf irregular galaxy NGC 4214, and can detect stellar groupings with sizes ranging from compact clusters to stellar complexes. In future work, the automatic selection method developed in this dissertation will be used to identify stellar groupings in a set of nearby galaxies to determine if the size scales for stellar clustering are uniform in the nearby universe or if it is dependent on local galactic environment. Once the stellar clusters and associations have been identified and age-dated, this information can be used to deduce disruption times from the age distribution as a function of the position of the stellar grouping within the galaxy, the size of the cluster or association, and the morphological type of the galaxy. The implications of these results for galaxy formation and evolution are discussed. / Dissertation/Thesis / Ph.D. Astrophysics 2011 Astrophysics Astronomy clustering galaxy size distribution star cluster stellar association stellar populations
100	The Galactic thick disk: a stellar population in its own right? / Galaxens tjocka disk: En stjärnfamilj i sin egen rätt? Rastau, Vlad January 2017 (has links) The Galactic disk is home of many billion stars, one of which isour Sun. The stellar population of which the Sun is a member residesin the vertically thin spiral structure of the disk. There is a seconddisk population, the so-called thick disk, that has somewhat dierentspatial, kinematic and chemical properties as compared to the thindisk. It may be systematically older than the thin disk (Bernkopf et al.2001), with a star-formation hiatus separating the two. Observationsof thick-disk subgiants allow us to probe the chemical properties ofthese stars. As the subgiant evolutionary phase is short, age-datingthese stars is also possible. Are they in fact systematically older thanthe oldest thin-disk stars? This project will take rst steps towardsanswering this question based on new target selections done on DataRelease 1 of the Gaia mission. / Vintergatans disk innehåller flera miljarder stjärnor, varav en är vår Sol. Den stjärnbefolkning som Solen är medlem i ligger i den vertikalt tunna spiralstrukturen på skivan (tunna disken). Det finns en andra diskpopulation, den så kallade tjocka disken, som har något annorlunda rumsliga, kinematiska och kemiska egenskaper jämfört med den tunna disken. Den kan vara äldren än tunna disken (Bernkopf et al. 2001), med en stjärnbildningsstopp som skiljer de två. Genom att observera subjättar som är en del av den tjocka disken blir det möjligt att analysera dessa stjärnors kemiska egenskaper. Eftersom subjätte grenen är en kort evolutionär fas, åldersbestämmelse är också möjlig för dessa stjärnor. Är de faktiskt systematiskt äldre än de äldsta tunna diskens stjärnor? Detta projekt kommer att ta de första stegen mot att svara på denna fråga baserat på nya målval som gjorts på Data Release 1 från Gaia-uppdraget. High resolution spectroscopy stellar atmospheres Galactic stellar populations Astronomy, Astrophysics and Cosmology Astronomi, astrofysik och kosmologi

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