Radiative and convective energy transport

David F. Gray

doi:10.1017/CBO9781316036570.010

This chapter is part of a book that is no longer available to purchase from Cambridge Core

7 - Radiative and convective energy transport

David F. Gray

Show author details

David F. Gray: Affiliation:
University of Western Ontario

Book contents

Get access

Summary

The dominant mechanism of energy transport through the surface layers of a typical star is radiation, i.e., photons. Transport by convection is often important below the surface, but rarely carries a significant fraction of the flux in the photosphere. Conduction comes into play in extreme cases such as white dwarfs. So it is radiative transfer that is our main focus here. It is in the domain of radiative transfer where the physical parameters of the material comprising the star are coupled to the spectrum we see and measure. We start by setting up the differential equation describing the flow of radiation through an infinitesimal volume. The integration of the equation can then be accomplished for the geometry of the situation. Unfortunately the step from a differential to an integral equation is not a physical solution to the problem because the integrand still depends on the atomic excitation of the material, which itself depends on the temperature of the material, and the radiation field in the material. Both the thermal (collisional) and the non-thermal (radiative) excitation vary with depth in the photosphere. In most applications of the theory to real stars, a numerical model of the star's photosphere is formed from which the integrand and then the spectrum of the star can be calculated. This chapter, along with Chapters 8 and 9, develops the tools for this modeling.

Information

Type: Chapter
Information: The Observation and Analysis of Stellar Photospheres , pp. 127 - 146

DOI: https://doi.org/10.1017/CBO9781316036570.010 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2005

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Abramowitz, M. & I.A., Stegun, eds. 1964. Handbook of Mathematical Functions, National Bureau of Standards Applied Math Series 55. (Washington, DC: National Bureau of Standards), p. 227.

Adelman, S.J., F., Kupka, & W.W., Weiss, eds. 1996. M.A.S.S. Model Atmospheres and Stellar Spectra. 5th Vienna Workshop, Ast. Soc. Pacific Conf. Ser. (San Francisco: Ast. Soc. Pacific).Google Scholar

Asplund, M., Å. Nordlund, R. Trampedach, & R.F., Stein, 1999. Ast. Ap. 346, L17.

Biermann, L. 1932. Z. f. Ap. 5, 117.

Biermann, L. 1938. Ast. Nachrichten 264, 395.CrossRef

Chandrasekhar, S. 1957. An Introduction to the Study of Stellar Structure. (New York: Dover), p. 55.Google Scholar

Defouw, R.J. 1970a. Solar Phys. 14, 42.CrossRef

Defouw, R.J. 1970b. Ap. J. 160, 659.CrossRef

Eddington, A.S. 1926. The Internal Constitution of the Stars, 1959 printing. (New York: Dover), pp. 322, 325.Google Scholar

Gray, D. F. 1988. Lectures on Spectral-Line Analysis: F, G, and K Stars. (Arva, Ontario: The Publisher).Google Scholar

Gray, D. F. 1989. Pub. Ast. Soc. Pacific 101, 832.CrossRef

Accessibility standard: Unknown

Accessibility compliance for the PDF of this book is currently unknown and may be updated in the future.