1 / 12

Lecture 8: Stellar Atmosphere

Lecture 8: Stellar Atmosphere. 3. Radiative transfer. Solar abundances from absorption lines. From an analysis of spectral lines, the following are the most abundant elements in the solar photosphere. Emission coefficient.

pillow
Download Presentation

Lecture 8: Stellar Atmosphere

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Lecture 8: Stellar Atmosphere 3. Radiative transfer

  2. Solar abundances from absorption lines • From an analysis of spectral lines, the following are the most abundant elements in the solar photosphere

  3. Emission coefficient • The emission coefficient is the opposite of the opacity: it quantifies processes which increase the intensity of radiation, • The emission coefficient has units of W/m/str/kg • Thus, accounting for both processes:

  4. Radiative transfer • This is the time independent radiative transfer equation • For a system in thermodynamic equilibrium (e.g. a blackbody), every process of absorption is perfectly balanced by an inverse process of emission. • Since the intensity is equal to the blackbody function and therefore constant throughout the box:

  5. Radiative transfer: general solution • i.e. the final intensity is the initial intensity, reduced by absorption, plus the emission at every point along the path, also reduced by absorption

  6. Example: homogeneous medium • Imagine a beam of light with Il,0 at s=0 entering a volume of gas of constant density, opacity and source function. • In the limit of high optical depth • In the limit of

  7. Approximate solutions • Approximation #1: Plane-parallel atmospheres • We can define a vertical optical depth such that • where • i.e. • and the transfer equation becomes

  8. Approximate solutions • Approximation #2: Gray atmospheres • Integrating the intensity and source function over all wavelengths, • We get the following simplified transfer equation • Integrating over all solid angles, • where Frad is the radiative flux through unit area

  9. The photon wind • In a spherically symmetric star with the origin at the centre • So the net radiative flux (i.e. movement of photons through the star) is driven by differences in the radiation pressure

  10. Approximate solutions • Approximation #3: An atmosphere in radiative equilibrium

  11. The Eddington approximation • To determine the temperature structure of the atmosphere, we need to establish the temperature dependence of the radiation pressure to solve: • Since • We need to assume something about the angular distribution of the intensity

  12. The Eddington approximation • This is the Eddington-Barbier relation: the surface flux is determined by the value of the source function at a vertical optical depth of 2/3

More Related