TY  - THES
A1  - Feldmeier, Achim
T1  - Hydrodynamics of astrophysical winds driven by scattering in spectral lines
N2  - Liniengetriebene Winde werden durch Impulsübertrag von Photonen auf ein Plasma bei Absorption oder Streuung in zahlreichen Spektrallinien beschleunigt. Dieser Prozess ist besonders effizient für ultraviolette Strahlung und Plasmatemperaturen zwischen 10^4 K und 10^5 K. Zu den astronomischen Objekten mit liniengetriebenen Winden gehören Sterne der Spektraltypen O, B und A, Wolf-Rayet-Sterne sowie Akkretionsscheiben verschiedenster Größenordnung, von Scheiben um junge Sterne und in kataklysmischen Veränderlichen bis zu Quasarscheiben. Es ist bislang nicht möglich, das vollständige Windproblem numerisch zu lösen, also die Hydrodynamik, den Strahlungstransport und das statistische Gleichgewicht dieser Strömungen gleichzeitig zu behandeln. Die Betonung liegt in dieser Arbeit auf der Windhydrodynamik, mit starken Vereinfachungen in den beiden anderen Gebieten.  Wegen persönlicher Beteiligung betrachte ich drei Themen im Detail.  1. Windinstabilität durch Dopplerde-shadowing des Gases. Die Instabilität bewirkt, dass Windgas in dichte Schalen komprimiert wird, die von starken Stoßfronten begrenzt sind. Schnelle Wolken entstehen im Raum zwischen den Schalen und stoßen mit diesen zusammen. Dies erzeugt Röntgenflashes, die die beobachtete Röntgenstrahlung heißer Sterne erklären können.  2. Wind runway durch radiative Wellen. Der runaway zeigt, warum beobachtete liniengetriebene Winde schnelle, kritische Lösungen anstelle von Brisenlösungen (oder shallow solutions) annehmen. Unter bestimmten Bedingungen stabilisiert der Wind sich auf masseüberladenen Lösungen, mit einem breiten, abbremsenden Bereich und Knicken im Geschwindigkeitsfeld.  3. Magnetische Winde von Akkretionsscheiben um Sterne oder in aktiven Galaxienzentren. Die Linienbeschleunigung wird hier durch die Zentrifugalkraft entlang korotierender poloidaler Magnetfelder und die Lorentzkraft aufgrund von Gradienten im toroidalen Feld unterstützt. Ein Wirbelblatt, das am inneren Scheibenrand beginnt, kann zu stark erhöhten Massenverlustraten führen.
N2  - Line driven winds are accelerated by the momentum transfer from photons to a plasma, by absorption and scattering in numerous spectral lines. Line driving is most efficient for ultraviolet radiation, and at plasma temperatures from 10^4 K to 10^5 K. Astronomical objects which show line driven winds include stars of spectral type O, B, and A, Wolf-Rayet stars, and accretion disks over a wide range of scales, from disks in young stellar objects and cataclysmic variables to quasar disks. It is not yet possible to solve the full wind problem numerically, and treat the combined hydrodynamics, radiative transfer, and statistical equilibrium of these flows. The emphasis in the present writing is on wind hydrodynamics, with severe simplifications in the other two areas.  I consider three topics in some detail, for reasons of personal involvement.  1. Wind instability, as caused by Doppler de-shadowing of gas parcels. The instability causes the wind gas to be compressed into dense shells enclosed by strong shocks. Fast clouds occur in the space between shells, and collide with the latter. This leads to X-ray flashes which may explain the observed X-ray emission from hot stars.  2. Wind runaway, as caused by a new type of radiative waves. The runaway may explain why observed line driven winds adopt fast, critical solutions instead of shallow (or breeze) solutions. Under certain conditions the wind settles on overloaded solutions, which show a broad deceleration region and kinks in their velocity law.  3. Magnetized winds, as launched from accretion disks around stars or in active galactic nuclei. Line driving is assisted by centrifugal forces along co-rotating poloidal magnetic field lines, and by Lorentz forces due to toroidal field gradients. A vortex sheet starting at the inner disk rim can lead to highly enhanced mass loss rates.
KW  - Hydrodynamik
KW  - Strahlungstransport
KW  - Sternwinde
KW  - Akkretionsscheiben
KW  - hydrodynamics
KW  - radiative transfer
KW  - stellar winds
KW  - accretion disks
Y1  - 2001
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-0000388
ER  - 
TY  - JOUR
A1  - Seiss, Martin
A1  - Spahn, Frank
T1  - Hydrodynamics of saturn's dense rings
JF  - Mathematical modelling of natural phenomena
N2  - The space missions Voyager and Cassini together with earthbound observations revealed a wealth of structures in Saturn's rings. There are, for example, waves being excited at ring positions which are in orbital resonance with Saturn's moons. Other structures can be assigned to embedded moons like empty gaps, moon induced wakes or S-shaped propeller features. Furthermore, irregular radial structures are observed in the range from 10 meters until kilometers. Here some of these structures will be discussed in the frame of hydrodynamical modeling of Saturn's dense rings. For this purpose we will characterize the physical properties of the ring particle ensemble by mean field quantities and point to the special behavior of the transport coefficients. We show that unperturbed rings can become unstable and how diffusion acts in the rings. Additionally, the alternative streamline formalism is introduced to describe perturbed regions of dense rings with applications to the wake damping and the dispersion relation of the density waves.
KW  - granular gas
KW  - instabilities
KW  - hydrodynamics
KW  - planetary rings
Y1  - 2011
U6  - https://doi.org/10.1051/mmnp/20116409
SN  - 0973-5348
SN  - 1760-6101
VL  - 6
IS  - 4
SP  - 191
EP  - 218
PB  - EDP Sciences
CY  - Les Ulis
ER  - 
TY  - GEN
A1  - Sandin, Christer
A1  - Steffen, Matthias
A1  - Jacob, Ralf
A1  - Schönberner, Detlef
A1  - Rühling, Ute
A1  - Hamann, Wolf-Rainer
A1  - Todt, Helge Tobias
T1  - The role of heat conduction to the formation of [WC]-type planetary nebulae
T2  - Proceedings of the International Astronomical Union
N2  - X-ray observations of young Planetary Nebulæ (PNe) have revealed diffuse emission in extended regions around both H-rich and  H-deficient central stars. In order to also repro-duce physical properties of H-deficient objects, we have, at first, extended our time-dependent radiation-hydrodynamic models with heat conduction for such conditions. Here we present some of the important physical concepts, which determine how and when a hot wind-blown bubble forms. In this study we have had to consider the, largely unknown, evolution of the CSPN, the slow (AGB) wind, the fast hot-CSPN wind, and the chemical composition. The main conclusion of our work is that heat conduction is needed to explain X-ray properties of wind-blown bubbles also in H-deficient objects.
T3  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 582 
KW  - conduction
KW  - hydrodynamics
KW  - planetary nebulae: general
Y1  - 2019
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-413702
SN  - 1866-8372
IS  - 582
SP  - 494
EP  - 495
ER  - 
TY  - JOUR
A1  - Parkin, E. R.
A1  - Broos, Patrick  S.
A1  - Townsley, L. K.
A1  - Pittard, J. M.
A1  - Moffat, Anthony F. J.
A1  - Naze, Y.
A1  - Rauw, G.
A1  - Oskinova, Lida
A1  - Waldron, W. L.
T1  - X-RAY EMISSION FROM THE DOUBLE-BINARY OB-STAR SYSTEM QZ CAR (HD 93206)
JF  - ASTROPHYSICAL JOURNAL SUPPLEMENT SERIES
N2  - X-ray observations of the double-binary OB-star system QZ Car (HD 93206) obtained with the Chandra X-ray Observatory over a period of roughly 2 years are presented. The respective orbits of systems A (O9.7 I+b2 v, P-A = 21 days) and B (O8 III+o9 v, P-B = 6 days) are reasonably well sampled by the observations, allowing the origin of the X-ray emission to be examined in detail. The X-ray spectra can be well fitted by an attenuated three-temperature thermal plasma model, characterized by cool, moderate, and hot plasma components at kT similar or equal to 0.2, 0.7, and 2 keV, respectively, and a circumstellar absorption of similar or equal to 0.2 x 10(22) cm(-2). Although the hot plasma component could be indicating the presence of wind-wind collision shocks in the system, the model fluxes calculated from spectral fits, with an average value of similar or equal to 7x10(-13) erg s(-1) cm(-2), do not show a clear correlation with the orbits of the two constituent binaries. A semi-analytical model of QZ Car reveals that a stable momentum balance may not be established in either system A or B. Yet, despite this, system B is expected to produce an observed X-ray flux well in excess of the observations. If one considers the wind of the O8 III star to be disrupted by mass transfer, the model and observations are in far better agreement, which lends support to the previous suggestion of mass transfer in the O8 III+o9 v binary. We conclude that the X-ray emission from QZ Car can be reasonably well accounted for by a combination of contributions mainly from the single stars and the mutual wind-wind collision between systems A and B.
KW  - hydrodynamics
KW  - stars: early-type
KW  - stars: individual (QZ Carinae)
KW  - stars: massive
KW  - stars: winds, outflows
KW  - X-rays: stars
Y1  - 2011
U6  - https://doi.org/10.1088/0067-0049/194/1/8
SN  - 0067-0049
VL  - 194
IS  - 1
PB  - IOP PUBLISHING LTD
CY  - BRISTOL
ER  - 
TY  - GEN
A1  - Seiß, Martin
A1  - Spahn, Frank
T1  - Hydrodynamics of Saturn’s dense rings
T2  - Postprints der Universität Potsdam : Postprint Mathematisch Naturwissenschaftliche Reihe
N2  - The space missions Voyager and Cassini together with earthbound observations re-vealed a wealth of structures in Saturn’s rings. There are, for example, waves being excited at ring positions which are in orbital resonance with Saturn’s moons. Other structures can be assigned to embedded moons like empty gaps, moon induced wakes or S-shaped propeller features. Further-more, irregular radial structures are observed in the range from 10 meters until kilometers. Here some of these structures will be discussed in the frame of hydrodynamical modeling of Saturn’s dense rings. For this purpose we will characterize the physical properties of the ring particle ensemble by mean field quantities and point to the special behavior of the transport coefficients. We show that unperturbed rings can become unstable and how diffusion acts in the rings. Additionally, the alternative streamline formalism is introduced to describe perturbed regions of dense rings with applications to the wake damping and the dispersion relation of the density waves.
T3  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 574 
KW  - granular gas
KW  - instabilities
KW  - hydrodynamics
KW  - planetary rings
Y1  - 2019
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-413139
SP  - 191
EP  - 218
ER  - 
TY  - THES
A1  - Klar, Jochen
T1  - A detailed view of filaments and sheets of the warm-hot intergalactic medium
T1  - Eine detaillierte Ansicht der Filamente und Ebenen des warm-heißen intergalaktischen Mediums
N2  - In the context of cosmological structure formation sheets, filaments and eventually halos form due to gravitational instabilities. It is noteworthy, that at all times, the majority of the baryons in the universe does not reside in the dense halos but in the filaments and the sheets of the intergalactic medium. While at higher redshifts of z > 2, these baryons can be detected via the absorption of light (originating from more distant sources) by neutral hydrogen at temperatures of T ~ 10^4 K (the Lyman-alpha forest), at lower redshifts only about 20 % can be found in this state. The remain (about 50 to 70 % of the total baryons mass) is unaccounted for by observational means. Numerical simulations predict that these missing baryons could reside in the filaments and sheets of the cosmic web at high temperatures of T = 10^4.5 - 10^7 K, but only at low to intermediate densities, and constitutes the warm-hot intergalactic medium (WHIM). The high temperatures of the WHIM are caused by the formation of shocks and the subsequent shock-heating of the gas. This results in a high degree of ionization and renders the reliable detection of the WHIM a challenging task. Recent high-resolution hydrodynamical simulations indicate that, at redshifts of z ~ 2, filaments are able to provide very massive galaxies with a significant amount of cool gas at temperatures of T ~ 10^4 K. This could have an important impact on the star-formation in those galaxies. It is therefore of principle importance to investigate the particular hydro- and thermodynamical conditions of these large filament structures. Density and temperature profiles, and velocity fields, are expected to leave their special imprint on spectroscopic observations. A potential multiphase structure may act as tracer in observational studies of the WHIM. In the context of cold streams, it is important to explore the processes, which regulate the amount of gas transported by the streams. This includes the time evolution of filaments, as well as possible quenching mechanisms. In this context, the halo mass range in which cold stream accretion occurs is of particular interest. In order to address these questions, we perform particular hydrodynamical simulations of very high resolution, and investigate the formation and evolution of prototype structures representing the typical filaments and sheets of the WHIM. We start with a comprehensive study of the one-dimensional collapse of a sinusoidal density perturbation (pancake formation) and examine the influence of radiative cooling, heating due to an UV background, thermal conduction, and the effect of small-scale perturbations given by the cosmological power spectrum. We use a set of simulations, parametrized by the wave length of the initial perturbation L. For L ~ 2 Mpc/h the collapse leads to shock-confined structures. As a result of radiative cooling and of heating due to an UV background, a relatively cold and dense core forms. With increasing L the core becomes denser and more concentrated. Thermal conduction enhances this trend and may lead to an evaporation of the core at very large L ~ 30 Mpc/h. When extending our simulations into three dimensions, instead of a pancake structure, we obtain a configuration consisting of well-defined sheets, filaments, and a gaseous halo. For L > 4 Mpc/h filaments form, which are fully confined by an accretion shock. As with the one-dimensional pancakes, they exhibit an isothermal core. Thus, our results confirm a multiphase structure, which may generate particular spectral tracers. We find that, after its formation, the core becomes shielded against further infall of gas onto the filament, and its mass content decreases with time. In the vicinity of the halo, the filament's core can be attributed to the cold streams found in other studies. We show, that the basic structure of these cold streams exists from the very beginning of the collapse process. Further on, the cross section of the streams is constricted by the outwards moving accretion shock of the halo. Thermal conduction leads to a complete evaporation of the cold stream for L > 6 Mpc/h. This corresponds to halos with a total mass higher than M_halo = 10^13 M_sun, and predicts that in more massive halos star-formation can not be sustained by cold streams. Far away from the gaseous halo, the temperature gradients in the filament are not sufficiently strong for thermal conduction to be effective.
N2  - Im Rahmen der kosmologischen Strukturbildung entstehen durch Gravitationsinstabilitäten Flächen, Filamente und schließlich Halos. Interessanterweise befinden sich zu jedem Zeitpunkt der kosmologischen Entwicklung der Großteil der Baryonen nicht in den Halos, sondern in den Filamenten und Ebenen des intergalaktischen Mediums. Während diese Baryonen bei höheren Rotverschiebungen (z ~ 2) noch in Form durch die Absorbtion von Licht (von weit entfernteren Quellen) durch neutralen Wasserstoff bei einer Temperatur von T ~ 10^4 K beobachtbar sind (Lyman-Alpha Wald), gilt dies bei niedrigeren Rotverschiebungen für nur noch ca. 20 % der Baryonen. Der überwiegende Teil (ca. 50-70 % der gesamten baryonischen Masse) sind bisher noch nicht direkt beobachtbar. Numerische Simulationen sagen jedoch voraus, das sich diese Baryonen in den Filamenten und Flächen des kosmischen Netzes befinden. Die entsprechende Gasverteilung zeichnet sich durch hohe Temperaturen T = 10^5 - 10^7 K und geringe bis mittlere Dichten aus und wird als warm-heißes intergalaktisches Medium (WHIM) bezeichnet. Die hohen Temperaturen entstehen in Folge der Bildung von Stoßwellen und der darauf folgenden Erhitzung des Gases (shock-heating). Das WHIM ist daher hochgradig ionisiert und sein verlässlicher Nachweis stellt eine große Herausforderung für die beobachtende Kosmologie dar. Neuere hydrodynamische Simulationen zeigen, dass sich bei höheren Rotverschiebungen von z ~ 2 Gasströmungen entlang der Filamente bilden, die massive Galaxien mit erheblichen Mengen an relativ kaltem Gas (T ~ 10^4 K) versorgen können. Dies hätte einen erheblichen Einfluss auf die Sternentstehung in diesen Galaxien. Es ist daher von grundsätzlichem Interesse, die spezifischen hydro- und thermodynamischen Bedingungen in den Strukturen des WHIM zu untersuchen. Sowohl Dichte- und Temperaturprofile als auch Geschwindigkeitsfelder prägen spektroskopische Beobachtungen. Eine mögliche Mehrphasenstruktur des WHIM könnte daher als Indikator in beobachtenden Studien dienen. Im Zusammenhang mit den kalten Strömen ist es besonders interessant, Prozesse zu untersuchen die den Zufluss von kaltem Gas zu den Galaxien regulieren. Dies umfasst die Zeitentwicklung des Anteils an kaltem Gas in den Filamenten, sowie mögliche Mechanismen, die zum Versiegen des Zuflusses von kaltem Gas auf die Galaxienscheibe führen. Um diese Zusammenhänge zu erforschen, führen wir spezielle hydrodynamische Simulationen mit sehr hoher Auflösung durch, die zu ausgewählten, wohldefinierten Strukturen führen, die das WHIM charakterisieren. Wir beginnen mit einer ausführlichen Untersuchung des eindimensionalen Kollaps einer sinusförmigen Störung (pancake formation). Hierbei untersuchen wir den Einfluss von Strahlungkühlung, Heizung durch den intergalaktischen UV Hintergrund, Wärmeleitung, sowie von kleinskaligen Störungen, welche dem kosmologischen Störungsspektrum folgen. Wir benutzen hierbei eine Reihe von Simulationen, welche die Längenskala der anfänglichen Störung L als Parameter verwenden. Für L ~ 2 Mpc/h führt der Kollaps zur Ausbildung einer Stoßwelle. Zusätzlich entsteht als Folge der Strahlungskühlung und der Heizung durch den UV Hintergrund ein relativ dichter und kalter isothermer Kern. Mit ansteigendem L wird dieser Kern dichter und kompakter. Durch Wärmeleitung reduziert sich die räumliche Ausdehnung des Kerns. Für L ~ 30 Mpc/h führt dies zu einem Verschwinden des Kerns. Mit der Erweiterung unserer Methodik auf dreidimensionale Simulationen, entsteht nun eine Konfiguration, welche aus wohldefinierten Flächen, Filamenten und einem gasförmigen Halo besteht. Für L > 4 Mpc/h, erhalten wir Filamente, die vollständig durch Akkretionsschocks begrenzt sind. Wie in unseren eindimensionalen Simulationen weisen auch sie einen isothermen Kern auf. Dies legt nahe, dass das WHIM eine Mehrphasenstruktur besitzt und mögliche Spektralsignaturen erzeugen kann. Nach seiner Entstehung ist der Kern gegen weiteren Zufluss von Gas abgeschirmt und seine Masse reduziert sich mit der Zeit. In der direkten Umgebung des Halos entspricht der Kern des Filamentes den oben angesprochenen kalten Strömen. Unsere Untersuchung zeigt, dass diese während der gesamten Entwicklung des Halos existent sind. In der weiteren Entwicklung werden sie durch den expandierenden Akkretionsschock des Halos verengt. Ab einer Skala von L > 6 Mpc/h kann Wärmeleitung zu einem Verschwinden des Zustroms von kaltem Gas führen. Diese Skala entspricht Halos mit einer Gesamtmasse von M_halo = 10^13 M_sun. Galaxien, die sich in noch massiveren Halos bilden, können daher nicht durch kalte Ströme mit Gas für die Sternentstehung versorgt werden. Im Filament, weit außerhalb des gasförmigen Halos, sind die Temperaturgradienten zu klein, um effiziente Wärmeleitung zu ermöglichen.
KW  - Kosmologie
KW  - Hydrodynamik
KW  - Intergalaktisches Medium
KW  - cosmology
KW  - hydrodynamics
KW  - intergalactic medium
Y1  - 2012
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus-58038
ER  - 
TY  - JOUR
A1  - Kurfuerst, P.
A1  - Feldmeier, Achim
A1  - Krticka, Jiri
T1  - Time-dependent modeling of extended thin decretion disks of critically rotating stars
JF  - Astronomy and astrophysics : an international weekly journal
N2  - Context. During their evolution massive stars can reach the phase of critical rotation when a further increase in rotational speed is no longer possible. Direct centrifugal ejection from a critically or near-critically rotating surface forms a gaseous equatorial decretion disk. Anomalous viscosity provides the efficient mechanism for transporting the angular momentum outwards. The outer part of the disk can extend up to a very large distance from the parent star.
 Aims. We study the evolution of density, radial and azimuthal velocity, and angular momentum loss rate of equatorial decretion disks out to very distant regions. We investigate how the physical characteristics of the disk depend on the distribution of temperature and viscosity.
 Methods. We calculated stationary models using the Newton-Raphson method. For time-dependent hydrodynamic modeling we developed the numerical code based on an explicit finite difference scheme on an Eulerian grid including full Navier-Stokes shear viscosity.
 Results. The sonic point distance and the maximum angular momentum loss rate strongly depend on the temperature profile and are almost independent of viscosity. The rotational velocity at large radii rapidly drops accordingly to temperature and viscosity distribution. The total amount of disk mass and the disk angular momentum increase with decreasing temperature and viscosity.
 Conclusions. The time-dependent one-dimensional models basically confirm the results obtained in the stationary models as well as the assumptions of the analytical approximations. Including full Navier-Stokes viscosity we systematically avoid the rotational velocity sign change at large radii. The unphysical drop of the rotational velocity and angular momentum loss at large radii (present in some models) can be avoided in the models with decreasing temperature and viscosity.
KW  - stars: mass-loss
KW  - stars: evolution
KW  - stars: rotation
KW  - hydrodynamics
Y1  - 2014
U6  - https://doi.org/10.1051/0004-6361/201424272
SN  - 0004-6361
SN  - 1432-0746
VL  - 569
PB  - EDP Sciences
CY  - Les Ulis
ER  - 
TY  - JOUR
A1  - Thomas, Timon
A1  - Feldmeier, Achim
T1  - Radiative waves in stellar winds with line scattering
JF  - Monthly notices of the Royal Astronomical Society
N2  - Photospheric radiation can drive winds from hot, massive stars by direct momentum transfer through scattering in bound-bound transitions of atmospheric ions. The line radiation force should cause a new radiative wave mode. The dispersion relation from perturbations of the line force was analysed so far either in Sobolev approximation or for pure line absorption. The former does not include the line-driven instability, and the latter cannot account for upstream propagating, radiative waves. We consider a non-Sobolev line force that includes scattering in a simplified way, accounting however for the important line-drag effect. We derive a new dispersion relation for radiative waves, and analyse wave propagation using Fourier methods, and by numerical solution of an integro-differential equation. The existence of an upstream propagating, dispersive radiative wave mode is demonstrated.
KW  - hydrodynamics
KW  - radiative transfer
KW  - waves
KW  - stars: winds
KW  - outflows
Y1  - 2016
U6  - https://doi.org/10.1093/mnras/stw1008
SN  - 0035-8711
SN  - 1365-2966
VL  - 460
SP  - 1923
EP  - 1933
PB  - Oxford Univ. Press
CY  - Oxford
ER  - 
TY  - JOUR
A1  - Sandin, C.
A1  - Steffen, M.
A1  - Schoenberner, D.
A1  - Rühling, Ute
T1  - Hot bubbles of planetary nebulae with hydrogen-deficient winds I. Heat conduction in a chemically stratified plasma
JF  - Frontiers in psychology
N2  - Heat conduction has been found a plausible solution to explain discrepancies between expected and measured temperatures in hot bubbles of planetary nebulae (PNe). While the heat conduction process depends on the chemical composition, to date it has been exclusively studied for pure hydrogen plasmas in PNe. A smaller population of PNe show hydrogen-deficient and helium-and carbon-enriched surfaces surrounded by bubbles of the same composition; considerable differences are expected in physical properties of these objects in comparison to the pure hydrogen case. The aim of this study is to explore how a chemistry-dependent formulation of the heat conduction affects physical properties and how it affects the X-ray emission from PN bubbles of hydrogen-deficient stars. We extend the description of heat conduction in our radiation hydrodynamics code to work with any chemical composition. We then compare the bubble-formation process with a representative PN model using both the new and the old descriptions. We also compare differences in the resulting X-ray temperature and luminosity observables of the two descriptions. The improved equations show that the heat conduction in our representative model of a hydrogen-deficient PN is nearly as efficient with the chemistry-dependent description; a lower value on the diffusion coefficient is compensated by a slightly steeper temperature gradient. The bubble becomes somewhat hotter with the improved equations, but differences are otherwise minute. The observable properties of the bubble in terms of the X-ray temperature and luminosity are seemingly unaffected.
KW  - conduction
KW  - hydrodynamics
KW  - planetary nebulae: general
KW  - stars: AGB and post-AGB
KW  - stars: Wolf-Rayet
KW  - X-rays: stars
Y1  - 2016
U6  - https://doi.org/10.1051/0004-6361/201527357
SN  - 1432-0746
VL  - 586
PB  - EDP Sciences
CY  - Les Ulis
ER  - 
TY  - JOUR
A1  - Kurfürst, P.
A1  - Feldmeier, Achim
A1  - Krticka, Jiri
T1  - Two-dimensional modeling of density and thermal structure of dense circumstellar outflowing disks
JF  - Astronomy and astrophysics : an international weekly journal
N2  - Context. Evolution of massive stars is affected by a significant loss of mass either via (nearly) spherically symmetric stellar winds or by aspherical mass-loss mechanisms, namely the outflowing equatorial disks. However, the scenario that leads to the formation of a disk or rings of gas and dust around massive stars is still under debate. It is also unclear how various forming physical mechanisms of the circumstellar environment affect its shape and density, as well as its kinematic and thermal structure. Results. Our models show the geometric distribution and contribution of viscous heating that begins to dominate in the central part of the disk for mass-loss rates higher than (M) over dot greater than or similar to 10(-10) M-circle dot yr(-1). In the models of dense viscous disks with (M) over dot > 10(-8) M-circle dot yr(-1), the viscosity increases the central temperature up to several tens of thousands of Kelvins, however the temperature rapidly drops with radius and with distance from the disk midplane. The high mass-loss rates and high viscosity lead to instabilities with significant waves or bumps in density and temperature in the very inner disk region. Conclusions. The two-dimensional radial-vertical models of dense outflowing disks including the full Navier-Stokes viscosity terms show very high temperatures that are however limited to only the central disk cores inside the optically thick area, while near the edge of the optically thick region the temperature may be low enough for the existence of neutral hydrogen, for example.
KW  - stars: massive
KW  - stars: mass-loss
KW  - stars: winds, outflows
KW  - stars: evolution
KW  - stars: rotation
KW  - hydrodynamics
Y1  - 2018
U6  - https://doi.org/10.1051/0004-6361/201731300
SN  - 1432-0746
VL  - 613
PB  - EDP Sciences
CY  - Les Ulis
ER  -