Book contents
- Frontmatter
- Contents
- Preface
- Conference Photograph
- Conference Participants
- Part one Stellar Evolution and Wind Theory
- Evolution of massive stars
- Evolution of AGB stars
- Hot star winds
- Axisymmetric outflows from single and binary stars
- Flows in clumpy CSM
- Part two Wolf-Rayet Ring Nebulae
- Part three Supernovae
- Part four Asymptotic Giant Branch stars
- Part five Planetary Nebulae
- Part six Novae and Symbiotic Stars
- Poster Papers
- Author Index
- Object Index
Hot star winds
from Part one - Stellar Evolution and Wind Theory
Published online by Cambridge University Press: 07 September 2010
- Frontmatter
- Contents
- Preface
- Conference Photograph
- Conference Participants
- Part one Stellar Evolution and Wind Theory
- Evolution of massive stars
- Evolution of AGB stars
- Hot star winds
- Axisymmetric outflows from single and binary stars
- Flows in clumpy CSM
- Part two Wolf-Rayet Ring Nebulae
- Part three Supernovae
- Part four Asymptotic Giant Branch stars
- Part five Planetary Nebulae
- Part six Novae and Symbiotic Stars
- Poster Papers
- Author Index
- Object Index
Summary
Abstract
Radiation pressure driven wind theory as applied to OB and related stars is reviewed, beginning with the first detailed formulation of the theory by Castor, Abbott & Klein (1975). The character of the line acceleration term in the equation of motion is discussed. The main successes of the time-independent theory are noted, along with its failures which motivated the more recent development of time-dependent (shocked-wind) theory.
Introduction
An early result from ultraviolet astronomy was that OB stars with bolometric magnitudes brighter than Mbol ≃ −6 suffer significant mass loss (Snow & Morton 1976). At about the same time the framework was laid down by Castor, Abbott & Klein (1975; hereafter CAK) for what, has proved since to be a very successful theory of mass loss from OB and other similarly high-luminosity stars. In bare outline the physical model is a simple one in which the outward force able to overcome gravity is the pressure exerted by the hot star's radiation field on its own atmosphere. In practical application, complexity arises from the fact that it is overwhelmingly the scattering of radiation in spectral lines that, mediates the force (a point first appreciated by Lucy & Solomon 1970).
- Type
- Chapter
- Information
- Circumstellar Media in Late Stages of Stellar Evolution , pp. 27 - 34Publisher: Cambridge University PressPrint publication year: 1994