Add to ORKGWe present a generalized formalism for treating the porosity-associated reduction in continuum opacity that occurs when individual clumps in a stochastic medium become optically thick. As in previous work, we concentrate on developing bridging laws between the limits of optically thin and thick clumps. We consider geometries resulting in either isotropic or anisotropic effective opacity, and, in addition to an idealized model in which all clumps have the same local overdensity and scale, we also treat an ensemble of clumps with optical depths set by Markovian statistics. This formalism is then applied to the specific case of boundfree absorption of X-rays in hot star winds, a process not directly affected by clumping in the optically thin l...
Context. Mass loss is essential for massive star evolution, thus also for the variety of a...
We consider the consequences of appreciable line optical depth for the profile shape of X-ray emissi...
International audience Aims: We investigate the impact of optically thick clumping on spectroscopic ...
We present a generalized formalism for treating the porosity-associated reduction in continuum opaci...
We present a generalised formalism for treating the porosity-associated reduction in continuum opaci...
We fit X-ray emission line profiles in high resolution XMM-Newton and Chandra grating spectra of the...
peer reviewedMassive stars possess powerful stellar winds. Studies over the last decade, including t...
We investigate the degree to which the nearly symmetric form of X- ray emission lines seen in Chandr...
Context.The mass-loss rate is a key parameter of massive stars. Adequate stellar atmosphere models a...
peer reviewedHigh-resolution X-ray spectra of O-type stars revealed less wind absorption than expect...
Aims. Both empirical evidence and theoretical findings indicate that the stellar winds of massive ea...
We investigate the degree to which the nearly symmetric form of X-ray emission lines seen in Chandra...
© ESO 2018. Context. Clumping in the radiation-driven winds of hot, massive stars severly affects t...
Aims. Both empirical evidence and theoretical findings indicate that the stellar winds of ...
By quantitatively fitting simple emission line profile models that include both atomic opacity and p...
Context. Mass loss is essential for massive star evolution, thus also for the variety of a...
We consider the consequences of appreciable line optical depth for the profile shape of X-ray emissi...
International audience Aims: We investigate the impact of optically thick clumping on spectroscopic ...
We present a generalized formalism for treating the porosity-associated reduction in continuum opaci...
We present a generalised formalism for treating the porosity-associated reduction in continuum opaci...
We fit X-ray emission line profiles in high resolution XMM-Newton and Chandra grating spectra of the...
peer reviewedMassive stars possess powerful stellar winds. Studies over the last decade, including t...
We investigate the degree to which the nearly symmetric form of X- ray emission lines seen in Chandr...
Context.The mass-loss rate is a key parameter of massive stars. Adequate stellar atmosphere models a...
peer reviewedHigh-resolution X-ray spectra of O-type stars revealed less wind absorption than expect...
Aims. Both empirical evidence and theoretical findings indicate that the stellar winds of massive ea...
We investigate the degree to which the nearly symmetric form of X-ray emission lines seen in Chandra...
© ESO 2018. Context. Clumping in the radiation-driven winds of hot, massive stars severly affects t...
Aims. Both empirical evidence and theoretical findings indicate that the stellar winds of ...
By quantitatively fitting simple emission line profile models that include both atomic opacity and p...
Context. Mass loss is essential for massive star evolution, thus also for the variety of a...
We consider the consequences of appreciable line optical depth for the profile shape of X-ray emissi...
International audience Aims: We investigate the impact of optically thick clumping on spectroscopic ...