Global ETD Search

11	An Assessment of Brown Dwarf Atmospheric Models Using Benchmark Brown Dwarfs Oswald, Wayne L. January 2020 (has links) No description available. Astronomy Astrophysics Physics Astronomy Substellar Brown Dwarf Spectra Cool Atmospheres
12	Lightning on exoplanets and brown dwarfs Hodosán, Gabriella January 2017 (has links) Lightning is an important electrical phenomenon, known to exist in several Solar System planets. Amongst others, it carries information on convection and cloud formation, and may be important for pre-biotic chemistry. Exoplanets and brown dwarfs have been shown to host environments appropriate for the initiation of lightning discharges. In this PhD project, I aim to determine if lightning on exoplanets and brown dwarfs can be more energetic than it is known from Solar System planets, what are the most promising signatures to look for, and if these "exo-lightning" signatures can be detected from Earth. This thesis focuses on three major topics. First I discuss a lightning climatology study of Earth, Jupiter, Saturn, and Venus. I apply the obtained lightning statistics to extrasolar planets in order to give a first estimate on lightning occurrence on exoplanets and brown dwarfs. Next, I introduce a short study of potential lightning activity on the exoplanet HAT-P-11b, based on previous radio observations. Related to this, I discuss a first estimate of observability of lightning from close brown dwarfs, with the optical Danish Telescope. The final part of my project focuses on a lightning radio model, which is applied to study the energy and radio power released from lightning discharges in hot giant gas planetary and brown dwarf atmospheres. The released energy determines the observability of signatures, and the effect lightning has on the local atmosphere of the object. This work combines knowledge obtained from planetary and earth sciences and uses that to learn more about extrasolar systems. My main results show that lightning on exoplanets may be more energetic than in the Solar System, supporting the possibility of future observations and detection of lightning activity on an extrasolar body. My work provides the base for future radio, optical, and infrared search for "exo-lightning".
13	Search for Close Binary Evolved Stars Saffer, R. A., Liebert, J. 10 1900 (has links) We report on a search for short -period binary systems composed of pairs of evolved stars. The search is being carried out concurrently with a program to characterize the kinematical properties of two different samples of stars. Each sample has produced one close binary candidate for which further spectroscopic observations are planned. We also recapitulate the discovery of a close detached binary system composed of two cool DA white dwarfs, and we discuss the null results of Ha observations of the suspected white dwarf /brown dwarf system G 29-38. Binary stars Brown dwarf stars Stellar evolution White dwarf stars Spectroscopy Asymptotic giant branch
14	High Dispersion Observations of H alpha in the Suspected Brown Dwarf, White Dwarf Binary System G29-38 Liebert, J., Saffer, R. A., Pilachowski, C. A. 10 1900 (has links) We report on high dispersion spectroscopy of the Ha absorption line of the cool DA white dwarf G 29 -38. This is the star for which a recently detected infrared excess has been suggested to be due to a possible brown dwarf companion by Zuckerman and Becklin (1986, 1987). Three echelle spectra obtained at the Multiple Mirror Telescope and at the Kitt Peak Mayall 4m telescope in 1987 December show no evidence for radial velocity variations larger than -'1.1 ± 8.7 km s -1 and are used to derive a weighted heliocentric radial velocity Vr = 33.7 ± 4.3 km s -1 for the white dwarf. No emission component from the hypothesized secondary star is detected. These negative results do not constitute strong evidence against the companion hypothesis, since the expected orbital velocity of the white dwarf component could be quite small, and the companion's line emission could be too faint to be detected. However, the observation of a sharp absorption line core restricts the possible rotation of the white dwarf to < 40 km s -1 and ensures that any surface magnetic field has a strength < 105 gauss. These results make it unlikely that the DA white dwarf has previously been in a cataclysmic variable accretion phase. Absorption spectra Brown dwarf stars H alpha emission line stars Infrared radiation White dwarf stars
15	Substellar companions to white dwarves Mullally, Fergal Robert, 1979- 28 August 2008 (has links) We search for planets and brown dwarves around white dwarves (WDs). Finding extra-solar planets is the first step toward establishing the existence and abundance of life in the Universe. The low mass and luminosity of WDs make them ideal stars to search for low mass companion objects. Theoretical predictions generally agree that a star will consume and destroy close-in, low mass planets as it ascends the red giant and asymptotic giant branch evolutionary tracks, but larger mass objects and those further out will survive. The matter ejected from the star as it evolves into a white dwarf may also be accreted onto daughter planets, or may coalesce into a disk from which planets can form. We employ two techniques to search for planets and brown dwarves (BDs) around WDs. A subset of pulsating white dwarf stars have a pulsational stability that rivals pulsars and atomic clocks. When a planet is in orbit around a such a star the orbital motion of the star around the centre of mass is detectable as a change in arrival times of the otherwise stable pulsations. We search for, and find, a sample of suitable pulsators, monitor them for between three and four years, and place limits on companions by constraining the variation consistent with a 2.4M[subscript J] planet in a 4.6 year orbit. We also observe a large sample of WDs to search for a mid-infrared excess caused by the presence of sub-stellar companions. We present evidence for a potential binary system consisting of a WD and a BD on the basis of an observed excess flux at near and mind-infrared wavelengths. We also place limits on the presence of planetary mass companions around those stars and compare our results to predictions of planetary survival theories. Our findings do not support suggestions of planet formation or accretion of extra mass during stellar death. White dwarf stars Brown dwarf stars Stars with planets Extrasolar planets--Detection Pulsating stars
16	Substellar companions to white dwarves Mullally, Fergal Robert, January 1900 (has links) Thesis (Ph. D.)--University of Texas at Austin, 2007. / Vita. Includes bibliographical references.
17	M dwarfs from the SDSS, 2MASS and WISE surveys : identification, characterisation and unresolved ultracool companionship Cook, Neil James January 2016 (has links) The aim of this thesis is to use a cross-match between WISE, 2MASS and SDSS to identify a large sample of M dwarfs. Through the careful characterisation and quality control of these M dwarfs I aim to identify rare systems (i.e. unresolved UCD companions, young M dwarfs, late M dwarfs and M dwarfs with common proper motion companions). Locating ultracool companions to M dwarfs is important for constraining low-mass formation models, the measurement of substellar dynamical masses and radii, and for testing ultracool evolutionary models. This is done by using an optimised method for identifying M dwarfs which may have unresolved ultracool companions. To do this I construct a catalogue of 440 694 M dwarf candidates, from WISE, 2MASS and SDSS, based on optical- and near-infrared colours and reduced proper motion. With strict reddening, photometric and quality constraints I isolate a sub-sample of 36 898 M dwarfs and search for possible mid-infrared M dwarf + ultracool dwarf candidates by comparing M dwarfs which have similar optical/near-infrared colours (chosen for their sensitivity to effective temperature and metallicity). I present 1 082 M dwarf + ultracool dwarf candidates for follow-up. Using simulated ultracool dwarf companions to M dwarfs, I estimate that the occurrence of unresolved ultracool companions amongst my M dwarf + ultracool dwarf candidates should be at least four times the average for my full M dwarf catalogue. I discuss yields of candidates based on my simulations. The possible contamination and bias from misidentified M dwarfs is then discussed, from chance alignments with other M dwarfs and UCDs, from chance alignments with giant stars, from chance alignments with galaxies, and from blended systems (via visual inspection). I then use optical spectra from LAMOST to spectral type a subset of my M dwarf + ultracool dwarf candidates. These candidates need confirming as true M dwarf + ultracool dwarf systems thus I present a new method I developed to use low resolution near-infrared spectra which relies on two colour similar objects (one an excess candidate, one not) having very similar spectra. A spectral difference of these two colour similar objects should leave the signature of a UCD in the residual of their differences, which I look for using the difference in two spectral bands designed to identify UCD spectral features. I then present the methods used to identify other rare systems from my full M dwarf catalogue. Young M dwarfs were identified by measuring equivalent widths of Hα from the LAMOST spectra, and by measuring rotation periods from Kepler 2 light curves. I identify late M dwarfs photometrically (using reduced proper motion and colour cuts) and spectroscopically (using the LAMOST spectra with spectral indices from the literature). Also I present common proper motion analysis aimed at finding Tycho-2 primaries for my M dwarfs and look for physically separated M dwarf + M dwarf pairs (internally within my full M dwarf catalogue). 523.8
18	Precision astrometry with adaptive optics: constraints on the mutual orbit of Luhman 16AB from GeMS Ammons, S. Mark, Garcia, E. Victor, Salama, Maissa, Neichel, Benoit, Lu, Jessica, Marois, Christian, Macintosh, Bruce, Savransky, Dmitry, Bendek, Eduardo, Guyon, Olivier, Marin, Eduardo, Garrel, Vincent, Sivo, Gaetano 02 September 2016 (has links) ELTs equipped with MCAO systems will be powerful astrometric tools in the next two decades. With sparse-field precisions exceeding 30 uas for V > 18, the ELTs will surpass even GAIA's per-epoch precision for faint stars (V > 12). We present results from an ongoing astrometry program with Gemini GeMS and discuss synergies with WFIRST and GAIA. First, we present a fit to the relative orbit of the individual L/T components of Luhman16 AB, the nearest brown dwarf binary known. Exploiting GeMS' wide field of view to image reference stars, we are able to track the relative motion to better than 0.2 mas. We find that a mutual Keplerian orbit with no perturbing planets fits the binary separation to within the measurement errors, ruling out companions down to 14 earth masses for certain orbits and periods. astrometry adaptive optics multi-conjugate tomography M92 NGC 1851 brown dwarf
19	Recherche de compagnons de type Jupiter à très grandes séparations autour d’étoiles jeunes dans le voisinage solaire Baron, Frédérique 12 1900 (has links) No description available. Naine brune Exoplanète Étoile jeune Imagerie Brown dwarf Exoplanet Young star Imaging
20	Caractérisation des signaux d'activité stellaire dans le système multiplanétaire Gliese 229 Deslières, Ariane 12 1900 (has links) Les exoplanètes peuvent être détectées par plusieurs méthodes. De celles-ci, la méthode des Vitesses Radiales (RV) est dite indirecte, car l'on observe le spectre lumineux de l'étoile hôte et non la planète directement. Or, plusieurs facteurs influencent les variations lumineuses d'une étoile hormis la présence d'un compagnon. La photosphère des étoiles comprend des régions plus sombres appelées taches stellaires causées par de forts champs magnétiques qui restreignent le déplacement de l'énergie vers la surface. Lorsque l'étoile tourne, elles se déplacent produisant ainsi des variations dans le spectre de l'étoile similaires à celles induites par les corps l'orbitant. C'est pourquoi la modélisation de l'activité stellaire est essentielle pour la recherche d'exoplanètes. Il existe maints indicateurs d'activité dont la photométrie et les bissectrices et le Full Width at Half Maximum (FWHM) obtenus du profil moyen des raies spectrales. Ils peuvent être modélisés à l'aide d'outils mathématiques comme les Processus Gaussiens (GP). L'étoile GL229 A est une naine rouge située à 5.75 parsecs autour de laquelle orbite la première naine brune, GL229 B, découverte par imagerie directe en 1995. À mi-chemin entre planètes géantes et étoiles naines, ces objets sous-stellaires n'ont pas acquis la masse nécessaire pour déclencher la fusion nucléaire de l'hydrogène lors de leur formation. Le système GL229 fut aussi observé par différents télescopes dotés d'instruments permettant d'obtenir des mesures de RV. Ceci mena, en 2014 et 2020, à la détection de deux exoplanètes, GL229 A b et A c aux masses minimales de 32 et 7 masses terrestres. Ce mémoire présente une réanalyse des RV obtenues avec HARPS, un spectrographe échelle. En modélisant le FWHM avec un GP, il peut être démontré que les signaux précédemment identifiés comme d'origine planétaire correspondent en fait à des signaux d'activité stellaire. / Several methods can detect exoplanets. Of these, the Radial Velocity (RV) method is said to be indirect because the light spectrum of the host star is observed and not the planet directly. However, several factors influence a star's luminous variations apart from a companion's presence. The photosphere of stars contains darker regions called star spots caused by strong magnetic fields that restrict the movement of energy to the surface. When the star rotates, these spots move, producing variations in the star's spectrum similar to those induced by the bodies orbiting it. Hence, stellar modelling activity is essential when searching for exoplanets. Many activity indicators, including photometry and bisectors and Full Width at Half Maximum (FWHM) obtained from the average spectral line profiles, can be modelled using tools such as Gaussian Processes (GP). GL229 A is a red dwarf located at 5.75 parsecs around which orbits a brown dwarf, GL229 B, firstly discovered through direct imaging in 1995. Halfway between giant planets and dwarf stars, these substellar objects did not acquire the mass necessary to trigger nuclear hydrogen fusion during their formation. The GL229 system was also observed by various telescopes equipped with instruments making it possible to obtain RV measurements. This led, in 2014 and 2020, to the detection of two exoplanets, GL229 A b and A c, with minimum masses of 32 and 7 Earth masses. This thesis presents a re-analysis of the RVs obtained from HARPS spectra, an échelle spectrograph, for the Gliese 229 system. By modelling the FWHM with a GP, we show that previously identified planetary signals are not real and result from stellar activity. Exoplanète Exoplanet Naine brune Brown dwarf Vitesse radiale Radial velocity Activité stellaire Stellar activity

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