Evolutionary sequences for H and He atmosphere massive white dwarf stars

Ramos, Gabriel Lauffer

January 2018

White dwarf stars are the most common final stage of stellar evolution, corresponding to 99% of all stars in the Galaxy. White dwarf models can be used to obtain the age of stellar populations, to build an initial to final mass relation to understand the connection between the properties of white dwarfs and their progenitors, determine the upper mass limit that separates white dwarfs progenitors from Type II supernovae, enhance the comprehension of the physical properties of high density matter and derive ages and masses for observed white dwarfs from the cooling tracks. The literature is populated with low mass and intermediate mass white dwarf models, however the massive white dwarfs are often forgotten and the evolutionary sequences are incomplete. In this dissertation, we compute full evolutionary sequences for massive white dwarfs, exploring the evolution of hydrogen-rich and hydrogen-deficient white dwarfs stars with masses between 1.012 and 1.307 M , and initial metallicity of Z = 0.02. These sequences are the result of main sequence stars with masses between 8.8 and 11.8 M . The simulations were performed with the Modules for Experiments in Stellar Astrophysics - MESA code, starting at the zero-age main sequence, through thermally pulsing and mass-loss phases, ending as the white dwarfs at the cooling sequence. Our simulations are full evolutionary, in which we consider the entire evolutionary history of the progenitors. We present reliable nuclear chemical profiles for the whole mass range considered, covering the different expected central compositions, i.e. C/O, O/Ne and Ne/O/Mg, and their dependence with the stellar mass. In addition, we present detailed chemical profiles of hybrid C/O-O/Ne core white dwarfs, found in the mass range between 1.024 and 1.150 M . We present the initial-to-final mass relation, mass-radius relation, and cooling times with improved crystallization limits, considering the effects of atmosphere and core composition.

Anãs brancas

Evolucao estelar

Métodos numéricos

Star evolution

Numerical methods

White dwarf

Probing the Gravitational Dependence of the Fine-Structure Constant from Observations of White Dwarf Stars

Bainbridge, Matthew, Barstow, Martin, Reindl, Nicole, Tchang-Brillet, W.-Ü, Ayres, Thomas, Webb, John, Barrow, John, Hu, Jiting, Holberg, Jay, Preval, Simon, Ubachs, Wim, Dzuba, Vladimir, Flambaum, Victor, Dumont, Vincent, Berengut, Julian

30 March 2017

Hot white dwarf stars are the ideal probe for a relationship between the fine-structure constant and strong gravitational fields, providing us with an opportunity for a direct observational test. We study a sample of hot white dwarf stars, combining far-UV spectroscopic observations, atomic physics, atmospheric modelling, and fundamental physics in the search for variation in the fine structure constant. This variation manifests as shifts in the observed wavelengths of absorption lines, such as quadruply ionized iron (FeV) and quadruply ionized nickel (NiV), when compared to laboratory wavelengths. Berengut et al. (Phys. Rev. Lett. 2013, 111, 010801) demonstrated the validity of such an analysis using high-resolution Space Telescope Imaging Spectrograph (STIS) spectra of G191-B2B. We have made three important improvements by: (a) using three new independent sets of laboratory wavelengths; (b) analysing a sample of objects; and (c) improving the methodology by incorporating robust techniques from previous studies towards quasars (the Many Multiplet method). A successful detection would be the first direct measurement of a gravitational field effect on a bare constant of nature. Here we describe our approach and present preliminary results from nine objects using both FeV and NiV.

varying constants

varying alpha

hot white dwarf stars

absorption spectra analysis

Evolutionary sequences for H and He atmosphere massive white dwarf stars / Sequências evolucionárias de estrelas anãs brancas massivas com atmosfera de H e He

Ramos, Gabriel Lauffer

January 2018

White dwarf stars are the most common final stage of stellar evolution, corresponding to 99% of all stars in the Galaxy. White dwarf models can be used to obtain the age of stellar populations, to build an initial to final mass relation to understand the connection between the properties of white dwarfs and their progenitors, determine the upper mass limit that separates white dwarfs progenitors from Type II supernovae, enhance the comprehension of the physical properties of high density matter and derive ages and masses for observed white dwarfs from the cooling tracks. The literature is populated with low mass and intermediate mass white dwarf models, however the massive white dwarfs are often forgotten and the evolutionary sequences are incomplete. In this dissertation, we compute full evolutionary sequences for massive white dwarfs, exploring the evolution of hydrogen-rich and hydrogen-deficient white dwarfs stars with masses between 1.012 and 1.307 M , and initial metallicity of Z = 0.02. These sequences are the result of main sequence stars with masses between 8.8 and 11.8 M . The simulations were performed with the Modules for Experiments in Stellar Astrophysics - MESA code, starting at the zero-age main sequence, through thermally pulsing and mass-loss phases, ending as the white dwarfs at the cooling sequence. Our simulations are full evolutionary, in which we consider the entire evolutionary history of the progenitors. We present reliable nuclear chemical profiles for the whole mass range considered, covering the different expected central compositions, i.e. C/O, O/Ne and Ne/O/Mg, and their dependence with the stellar mass. In addition, we present detailed chemical profiles of hybrid C/O-O/Ne core white dwarfs, found in the mass range between 1.024 and 1.150 M . We present the initial-to-final mass relation, mass-radius relation, and cooling times with improved crystallization limits, considering the effects of atmosphere and core composition.

Anãs brancas

Evolucao estelar

Métodos numéricos

Star evolution

Numerical methods

White dwarf

The Detection and Description of Symbiotic Accretion From Cool Evolved Stars

Lucy, Adrian B.

January 2021

Symbiotic stars are binaries consisting of a cool evolved G-M/S/C I-III star accreting onto a smaller companion---but the accretion disk itself is rarely detected. Accretion signatures like hard X-rays and optical/ultraviolet flickering are usually suppressed or outshone by shell burning on the accreting white dwarf, the luminous giant, and the giant's wind nebula. In Chapters 2 and 3, we present a new way to find symbiotics that is less biased against accreting-only, non-burning symbiotics with directly detectable accretion disks. Our search methodology is based on finding outliers in SkyMapper Southern Sky Survey broad-band and intermediate-band photometry, using a parameter space built from reconstructed u-g u-v snapshot colors and rapid variability between the three exposures of a 20-minute SkyMapper Main Survey filter sequence, from a sample of luminous red objects selected with 2MASS and Gaia. In a pilot survey employing this new search design, we discovered 12 new symbiotics, including four symbiotics with optical accretion disk flickering and at least two with boundary-layer hard X-rays, as well as 10 new symbiotic candidates. We also discovered optical flickering in the known symbiotic V1044 Cen (CD-36 8436). We conclude that at least 20% of the true population of symbiotics exhibits detectable optical flickering from the inner accretion disk, a substantial fraction of which would not meet the usual H-alpha equivalent width detection thresholds typically used to find symbiotics with traditional narrow-band emission line photometry surveys. There is a significant population of optically-flickering symbiotics hidden both within and beyond the known catalogs of symbiotic stars---however, the question of whether the true population of accreting-only symbiotics is larger than the population of burning symbiotics remains unanswered. We also find that our methods probe a completely different region of parameter space than recent work by the Munari et al. (2021) search for accreting-only symbiotics, while being surprisingly in harmony with the Akras et al. (2019) infrared selection criteria. As an intermediate step in our pilot survey, we explored several outlying regions in our SkyMapper parameter space with optical spectroscopy of 234 luminous red objects, which we present in a 248-page spectral atlas. Our results identify a zone of the u-g u-v snapshot color-color diagram in which virtually all objects are symbiotics. When all-sky uvg colors become available through future DRs of SkyMapper and MEPHISTO, between about 51 and 117 symbiotics missed by previous surveys (of which 11 to 17 have been reported in this work) will be discoverable using only this mostly-symbiotic zone of the color-color diagram, with a near-zero contamination rate. Main Survey filter-sequence variability is also a powerful tool for finding hidden, flickering symbiotics both inside and outside of the mostly-symbiotic color-color zone, but variability must still be used in conjunction with color; there must be enough of an accretion disk contribution to the u-band for it to exhibit detectable variability. We show that yellow post-AGB stars with strong Balmer jump absorption (along with the symbiotic Southern Crab) are outliers with large positive u-v, while some S and carbon stars are outliers with large negative u-v. We also show that it is important to correct the results of SkyMapper's catalog pipeline for variability when dealing with samples containing large-amplitude pulsating stars. In Chapters 4 and 5, we present an in-depth study of one of the few optically-flickering symbiotic stars previously known, MWC 560 (V694 Mon). The persistent outflow from MWC 560 is known to manifest as broad absorption lines (BALs), most prominently at the Balmer transitions. In Chapter 4, we report the detection of high-ionization BALs from C IV, Si IV, N V, and He II in International Ultraviolet Explorer spectra obtained on 1990 April 29-30, when an optical outburst temporarily erased the obscuring "iron curtain" of absorption troughs from Fe II and similar ions. The C IV and Si IV BALs reached maximum radial velocities at least 1000 km/s higher than contemporaneous Mg II and He II BALs; the same behaviors occur in the winds of quasars and cataclysmic variables. An iron curtain lifts to unveil high-ionization BALs during the P Cygni phase observed in some novae, suggesting by analogy a temporary switch in MWC 560 from persistent outflow to discrete mass ejection. At least three more symbiotic stars exhibit broad absorption with blue edges faster than 1500 km/s; high-ionization BALs have been reported in AS 304 (V4018 Sgr), while transient Balmer BALs have been reported in Z And and CH Cyg. These BAL-producing fast outflows can have wider opening angles than has been previously supposed. BAL symbiotics are short-timescale laboratories for their giga-scale analogs, broad absorption line quasars (BALQSOs), which display a similarly wide range of ionization states in their winds. In Chapter 5, we investigate how the accretion disc of MWC 560 is affected by its outflow. We performed optical, radio, X-ray, and ultraviolet observations of MWC 560 during its 2016 optical high state. We tracked multi-wavelength changes that signalled an abrupt increase in outflow power at the initiation of a months-long outflow fast state, just as the optical flux peaked: (1) an abrupt doubling of Balmer absorption velocities; (2) the onset of a 20 𝜇Jy/month increase in radio flux; and (3) an order-of-magnitude increase in soft X-ray flux. Juxtaposing to prior X-ray observations and their coeval optical spectra, we infer that both high-velocity and low-velocity optical outflow components must be simultaneously present to yield a large soft X-ray flux, which may originate in shocks where these fast and slow absorbers collide. Our optical and ultraviolet spectra indicate that the broad absorption-line gas was fast, stable, and dense (⪞10⁶.⁵ cm⁻³) throughout the 2016 outflow fast state, steadily feeding a lower-density (⪝10⁵.⁵ cm⁻³) region of radio-emitting gas. Persistent optical and ultraviolet flickering indicate that the accretion disc remained intact. The stability of these properties in 2016 contrasts to their instability during MWC 560's 1990 outburst, even though the disc reached a similar accretion rate. We propose that the self-regulatory effect of a steady fast outflow from the disc in 2016 prevented a catastrophic ejection of the inner disc. This behaviour in a symbiotic binary resembles disc/outflow relationships governing accretion state changes in X-ray binaries.

Astronomy

Astrophysics

Cool stars

White dwarf stars

Stars--Color

Accretion (Astrophysics)

Decomposition of the Globular Cluster NGC 6397

Tsui, Hong

06 1900

The kinematics and white dwarf distribution have been studied for the Globular Cluster NGC 6397. The data was obtained from NASA’s Hubble Space Telescope in 2005. In particular, we used the images of a field 5’ Southeast of the core of NGC 6397 from Advanced Camera for Surveys to conduct our analyses. The first part of the study is about the kinematics of the globular cluster. Isotropy of velocity distribution and cluster rotation have been considered. As anticipated, this relaxed cluster exhibited no strong signs of anisotropy. However, there appears to be some level of rotation. The rotational motion turns out to be mu sub alpha cos(delta) = 3.88 ± 1.41 mas yr −1 and mu sub delta = −14.83 ± 0.58 mas yr −1. This result is not entirely expected and deserves further investigation in future studies. The second of the thesis is based on white dwarf populations in the globular cluster and the Galactic Bulge. As a first glance, there appears to be a lacking of white dwarfs at the age of approximately 0.6 Gyr. Further investigation reveals this to be statistically insignificant. Through this analysis, another pattern of white dwarf abundance is discovered. There appeared to be much more stars at the age between 0.9 − 2.0 Gyr. This could be a manifestation of modeling error. As the final consideration of this thesis, white dwarf candidates in the Galactic Bulge are illustrated. Approximately 10 candidates are found at the most probable location of stars in the Bulge. The analyses conducted in this thesis set stage for further development in understanding of globular clusters. In particular, the rotation analysis raises curiosity about the dynamics of NGC 6397 in the plane of the sky. Moreover, the velocity distribution analysis confirms properties and theories pertaining to globular clusters.

NGC 6397

white dwarf

rotation

galactic bulge

velocity distribution

globular cluster

Jeans mass

Jeans length

anisotropy

Milky Way

Candidate isolated neutron stars and other stellar x-ray sources from the ROSAT all-sky and Sloan Digital Sky Surveys /

Agüeros, Marcel A.

January 2006

Thesis (Ph. D.)--University of Washington, 2006. / Vita. Includes bibliographical references (p. 139-145).

Analyse de l'absorption circumstellaire de WD 1145+017

Fortin-Archambault, Maude

08 1900

WD 1145+017 est une étoile naine blanche polluée par des métaux avec un astéroïde en décomposition autour d’elle. Ce système est le premier à montrer la phase de décomposition active de l’objet polluant, et permet d’en apprendre sur cette phase du phénomène d’accrétion. Les différentes observations montrent un système très complexe qui est composé de plusieurs morceaux de l’objet rocheux, d’un disque de poussière et d’un disque de gaz, tous en orbite autour de la naine blanche polluée. Nous présentons un modèle de disque de gaz excentrique en précession conçu pour l’étude des zones d’absorption circumstellaire variables détectées pour WD 1145+017. Ce modèle, inspiré de celui récemment présenté par Cauley et al., calcule explicitement l’opacité du gaz pour toutes conditions physiques du disque prédéterminées et prédit la force et la forme de toutes les zones d’absorption, de l’ultraviolet au visible, à n’importe quelle phase du cycle de précession. Les réussites et échecs de ce modèle simple fournissent de l’information précieuse concernant les caractéristiques physiques du gaz qui entoure l’étoile, entre autres sa composition chimique, sa température et sa densité. Le modèle de disque excentrique met aussi en évidence le besoin de composantes supplémentaires, probablement des anneaux circulaires, pour expliquer la présence d’absorption à décalage de vitesse nul ainsi que celle de raies de Si hautement ionisé. Nous trouvons qu’une période de précession de 4.6±0.3 ans peut reproduire avec succès la forme et le profil de vitesse observé pour la majorité des époques d’observation d’avril 2015 à janvier 2018, bien que des différences mineures à certains moments indiquent que la configuration géométrique supposée n’est probablement pas encore optimale. Finalement, nous montrons que notre modèle peut expliquer quantitativement le changement morphologique des zones d’absorption durant les transits de l’objet en orbite autour de l’étoile. / WD 1145+017 is a metal polluted white dwarf with an actively disintegrating asteroid orbiting around it. This system is the first to show the active decomposition phase of the accretion process. The different observed data show a complex system composed of many pieces of the rocky objets, a dust disk and a gaseous disk, all orbiting the polluted white dwarf. We present an eccentric precessing gas disk model designed to study the variable circumstellar absorption features detected for WD 1145+017. This model, inspired by one recently proposed by Cauley et al., calculates explicitly the gas opacity for any predetermined physical conditions in the disk, predicting the strength and shape of all absorption features, from the UV to the optical, at any given phase of the precession cycle. The successes and failures of this simple model provide valuable insight on the physical characteristics of the gas surrounding the star, notably its composition, temperature and density. This eccentric disk model also highlights the need for supplementary components, most likely circular rings, in order to explain the presence of zero velocity absorption as well as highly ionized Si lines. We find that a precession period of 4.6±0.3 yrs can successfully reproduce the shape of the velocity profile observed at most epochs from April 2015 to January 2018, although minor discrepancies at certain times indicate that the assumed geometric configuration may not be optimal yet. Finally, we show that our model can quantitatively explain the change in morphology of the circumstellar feature during transiting events.

Étoile naine blanche

Disque circumstellaire

White dwarf star

Circumstellar disk

Physique

Astrophysique et astrophysique

Physics

Astronomy and astrophysics

Conception d'un environnement de simulation pour le calcul des profils d'élargissement Stark des raies d'hélium neutre

Tremblay, Patrick

06 1900

Ce mémoire porte sur l'étude des étoiles naines blanches de type DB, dont le spectre est dominé par les raies d’hélium neutre. Des travaux récents ont révélé que les paramètres physiques mesurés à l'aide de la méthode dite spectroscopique —notamment la température effective et la masse de l'étoile — posaient problème pour ce type de naine blanche. Nous avons dans cette étude réexaminé un des ingrédients essentiels de cette méthode, soit le calcul de profils d'élargissement Stark des raies d'hélium neutre. Ce problème fut abordé il y a 25 ans par notre groupe de recherche en utilisant la théorie standard de l'élargissement Stark. Les profils semi-analytiques calculés dans le cadre de cette théorie considèrent les électrons comme étant dynamiques et les ions statiques. Avec l'amélioration de la puissance numérique des ordinateurs, d’autres groupes de recherche ont grandement amélioré le traitement de l'élargissement Stark en produisant des simulations numériques décrivant en détail la dynamique et les interactions des perturbateurs (ions et électrons) près de l'émetteur (l'atome d'hélium dans notre cas). Ils n'ont cependant généré de tables de profils Stark, applicables au calcul de spectres synthétiques d'étoiles naines blanches, que pour deux raies de l'atome d'hélium. Dans ce mémoire, nous décrivons la conception de notre propre environnement de simulation incluant certains aspects importants considérés dans les travaux précédents (unification du traitement des ions et électrons, correction pour la dynamique des ions, transition de la contribution des électrons à l'élargissement, du coeur aux ailes du profil, intégration numérique de l'opérateur quantique d'évolution temporelle de l'hélium perturbé par un champ électrique fluctuant, correction de Debye pour la corrélation du mouvement des perturbateurs chargés, variation de densité locale et réinjection de particules) afin de mieux représenter l'environnement dynamique de l'atome d'hélium. Des étapes intermédiaires, comme la construction de l'espace de simulation et le modèle quasi-statique, nous ont permis de valider cet espace de simulation ainsi que le respect de la statistique du système. Une fois ces étapes de validation franchies, nous avons produit des grilles de profils Stark pour les deux raies les plus importantes de l'atome d'hélium dans le domaine du visible, soit He ɪ λ4471 et He ɪ λ4922, pour des températures entre 10,000 K et 40,000 K et des densités électroniques entre 1 × 10¹⁴ cm⁻³ et 6 × 10¹⁷ cm⁻³. Une comparaison avec d'autres résultats publiés démontre que nos calculs rivalisent avec les meilleurs profils obtenus dans le domaine des simulations numériques de l'élargissement Stark. L'élaboration de cet outil ouvre la voie à la création d'une nouvelle génération de modèles d'atmosphères de naines blanches qui nous permettra de raffiner l'analyse spectroscopique de ces objets. / This thesis deals with the study of white dwarf stars of the DB type, whose spectrum is dominated by neutral helium lines. Recent work has revealed that physical parameters — namely the effective temperature and the stellar mass — measured using the so-called spectroscopic technique are problematic for this type of white dwarf. In this study, we re-examine one of the essential ingredients of this method, namely the calculation of Stark broadening profiles of neutral helium lines. This problem was addressed 25 years ago by our research group using the standard Stark broadening theory. Semi-analytical profiles calculated under this theory consider electrons as dynamic and ions as static. With the improvement of computer numerical power, other research groups have significantly improved the treatment of Stark brodening by producing numerical simulations describing in detail the dynamics and interactions of the perturbers (ions and electrons) near the emitter (the helium atom in our case). However, they generated Stark profile tables, applicable to the computation of synthetic spectra for white dwarf stars, for only two lines of the helium atom. In this thesis, we describe the creation of our own simulation environment including some important aspects considered in previous work (unification of ion and electron treatment, correction for ion dynamics, transition of the electron contribution to broadening from the core to the wings of the profile, numerical integration of the quantum operator of the time evolution of helium perturbed by a fluctuating electric field, Debye correction for the correlation of the motion of charged perturbers, local density variation and particle reinjection) in order to better represent the dynamical environment of the helium atom. Intermediate steps, such as the construction of the simulation space and the quasi-static model, allowed us to validate this simulation space and the respect of the system statistics. Once these validation steps were completed, we produced grids of Stark profiles for the two most important lines of the helium atom in the optical, namely He ɪ λ4471 et He ɪ λ4922, for temperatures between 10,000 K and 40,000 K and electronic densities between 1 × 10¹⁴ cm⁻³ and 6 × 10¹⁷ cm⁻³. A comparison with other published results shows that our calculations rival the best profiles obtained in the field of numerical simulations of Stark broadening. The development of this tool paves the way for the creation of a new generation of white dwarf atmosphere models that will allow us to refine the spectroscopic analysis of these objects.

étoiles : atmosphères

matière dense

naines blanches

opacité

raies : profils

simulation numérique

dense matter

line : profiles

numerical simulation

opacity

quantum physics

stars : atmosphere

white dwarf

Observations de pulsateurs compacts à l'aide de la caméra Mont4K CCD

Francoeur, Myriam

12 1900

Les pulsateurs compacts sont des étoiles présentant des variations intrinsèques de luminosité dont les gravités de surface sont supérieures à 100,000 cm/s² On retrouve parmi ces objets deux familles des sous-naines chaudes de type B (sdB) pulsantes et quatre familles distinctes de naines blanches pulsantes. Dans le but d'observer les pulsations de tels objets pour ensuite analyser leur propriétés grâce à l'astéroséismologie, l'Université de Montréal, en collaboration avec le Imaging Technology Laboratory (ITL - University of Arizona), a développé la caméra Mont4K (Montreal4K) CCD qui est, depuis le printemps 2007, le principal détecteur employé au télescope Kuiper de 1.55 m du Mt Bigelow (Steward Observatory, University of Arizona). à l'aide de ce montage, des observations ont été menées pour quelques-uns de ces pulsateurs compacts. La première cible fut HS 0702+6043, un pulsateur hybride. Une importante mission pour cet objet, réalisée du 1er novembre 2007 au 14 mars 2008, a permis d'identifier 28 modes de pulsations pour cet objet en plus de mettre en évidence pour certains de ces modes d'importantes variations d'amplitude. Deux autres cibles furent les naines blanches pulsantes au carbone de type « Hot DQ » SDSS J220029.08-074121.5 et SDSS J234843.30-094245.3. Il fut possible de montrer de façon indirecte la présence d'un fort champ magnétique à la surface de J220029.08-074121.5 grâce à la présence de la première harmonique du mode principal. En outre, pour ces deux cibles, on a pu conclure que celles-ci font bel et bien partie de la classe des naines blanches pulsantes au carbone. / Compact pulsators are stars with surface gravities larger than 100,000 cm/s² showing intrisinc luminosity variations. Six different classes of such objects are known, including two pulsating hot subdwarf (sdB), and four pulsating white dwarf classes. In order to observe their pulsations and further analyze their properties through asteroseismology, the Universit\'e de Montr\'eal, in collaboration with the University of Arizona Imaging Instrument Laboratory, developed the Mont4K (Montreal4K) CCD camera which is the primary science detector of the Kuiper 1.55 m telescope at Mt Bigelow since Spring 2007. With this setup, several compact pulsators were targeted. The first target was the hybrid pulsator HS 0702+6043, observed from November 1st 2007 to March 14th 2008, for which 28 pulsation modes were isolated. Moreover, it was possible to highlight important amplitude variations in some of these modes. Two Hot DQ white dwarf pulsators, SDSS J220029.08-074121.5 and SDSS J234843.30-094245.3, were also targeted. In the case of J220029.08-074121.5, it was possible to highlight the presence of a strong magnetic field at its surface through the presence of the first harmonic of the main pulsation mode of this object. Furthermore, the follow-up campaigns on J220029.08-074121.5 and J234843.30-094245.3 allowed to classify these two white dwarf as Hot DQ pulsators.

étoiles

stars

oscillations

oscillations

sous-naine chaude

hot subdwarf

naine blanche

white dwarf

astéroséismologie

asteroseismology

photométrie

photometry

HS 0702+6043

HS 0702+6043

J2200-0741

J2200-0741

J2348-0942

J2348-0942

Mont4K CCD

Mont4K CCD

X-ray Diagnostics of Accretion Plasmas in Selected Soft Polars / Akkretionsplasmen in Polaren mit ausgeprägter weicher Röntgenstrahlung

Traulsen, Iris

06 March 2009

No description available.

520 Astronomie

Mathematics and Computer Science

Kataklysmischer Doppelstern

Weißer Zwerg

Röntgenspektroskopie

XMM-Newton

Cataclysmic variable

White dwarf

X-ray spectroscopy

XMM-Newton

39.40

TBK 000: Hochenergieastronomie

THT 700: Kompakte Sterne {Astronomie}

THT 900: Doppelsterne {Astronomie}