Your search keyword '"A. C. Wawrzyn"' showing total 3 results

1. Structure and spectra of irradiated secondaries in close binaries

Author

Travis Barman, Katrina Exter, Peter H. Hauschildt, Hans Moritz Günther, and A. C. Wawrzyn

Subjects

Physics, Stars, Common envelope, Space and Planetary Science, Binary star, Stellar atmosphere, Cataclysmic variable star, Astronomy, Astronomy and Astrophysics, Context (language use), Astrophysics, Effective temperature, Luminosity

Abstract

Context. The standard stellar model atmosphere ignores the influence of external radiation. This assumption, while sufficient for most stars, fails for many short-period binaries. Aims. In setting up combined model atmospheres for close binaries, we want to constrain the parameters of both components, especially in the case of a hot primary component strongly influencing its cool secondary companion. This situation can be found after common envelope evolution (CEE). The status of both components today allows one to retrace the CEE itself. Methods. We used our stellar atmosphere code PHOENIX, which includes the effect of irradiation in its radiation transport equation, to investigate the close binary star UU Sge. We combined our calculated spectra of both components, weighted by their visible size, and adjusted the input parameters until reasonable agreement with observations is reached. Results. We derive a range of 80 000−85 000 K for the effective temperature of the primary (Teff, p) and give a rough estimate for the primary’s abundances, particularly the nitrogen enrichment. The heated day-side of the secondary has an apparent “effective” or equilibrium temperature of 24 000−26 000 K, nearly independent of its intrinsic luminosity. It shows an enhancement in nitrogen and carbon. Conclusions. The evolution of the primary and secondary stars were strongly influenced by the other’s presence. Radiation from the primary on the secondary’s day-side is still an important factor in understanding the secondary’s atmospheric structure.

Published

2009

2. A method to simulate inhomogeneously irradiated objects with a superposition of 1D models

Author

H. M. Guenther and A. C. Wawrzyn

Subjects

Physics, Physics::Instrumentation and Detectors, Physics::Medical Physics, Binary number, FOS: Physical sciences, Astronomy and Astrophysics, Astrophysics, Astronomical spectroscopy, Ion, Computational physics, Superposition principle, Astrophysics - Solar and Stellar Astrophysics, Space and Planetary Science, Ionization, Projected area, Irradiation, Astrophysics::Earth and Planetary Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics, Instrumentation and Methods for Astrophysics (astro-ph.IM), Solar and Stellar Astrophysics (astro-ph.SR), Line (formation)

Abstract

In close binary systems the atmosphere of one or both components can be significantly influenced by irradiation from the companion. Often the irradiated atmosphere is simulated with a single-temperature approximation for the entire half-sphere. We present a scheme to take the varying irradiation angle into account by combining several separate 1D models. This is independent of the actual code which provides the separate stellar spectra. We calculate the projected area of zones with given irradiation angle and use this geometrical factor to scale separate 1D models. As an example we calculate two different irradiation scenarios with the PHOENIX code. The scheme to calculate the projected area is applicable independent of the physical mechanism that forms these zones. In the case of irradiation by a primary with T=125000 K, the secondary forms ions at different ionisation states for different irradiation angles. No single irradiation angle exists which provides an accurate description of the spectrum. We show a similar simulation for weaker irradiation, where the profile of the H$\alpha$ line depends on the irradiation angle., Comment: published in A&A

Published

2011

3. Geometry of irradiated stars

Author

A. C. Wawrzyn, H. M. Günther, T. S. Barman, P. H. Hauschildt, and Eric Stempels

Subjects

Physics, Stars, Optics, Line-of-sight, business.industry, Numerical analysis, Binary star, Phase (waves), Projected area, Astrophysics::Earth and Planetary Astrophysics, business, Spectral line, Numerical integration

Abstract

The physical conditions in a variety of objects (e.g. hot exoplanets and close binaries) are fundamentally influenced by external irradiation. In static cases this leads to the development of zones of different temperatures on the ‘day‐side’. In order to combine spectra from all zones to a full visible circular disk and to obtain a 1.5D spectrum we need to calculate the weight of each patch. In the following we present the geometrical considerations and calculate the observed projected area of constant temperature in an irradiated object for specific re‐radiation angles. This allows non‐isotropic models to be used. We supply an IDL code to calculate the observed projected area for any patch given the phase and angle between surface and line of sight as well as a proper weighting for each by numerical integration. We end up with a simple approach to upgrade a 1D irradiation model to a quasi 1.5D one. This method can be applied e.g. to irradiated secondaries in close binaries.

Published

2009