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13: Formation of Spectral Lines

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    141686

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    • 13.1: Introduction
      This page explains the importance of dark spectral lines in star spectra caused by atomic transitions in prevalent elements. It highlights the challenge of distinguishing between line and continuum absorption, which can introduce errors in spectral analysis. The current method focuses on synthesizing the complete spectrum for greater accuracy, while traditional approaches remain in use to separate specific line processes from surrounding absorption.
    • 13.2: Terms and Definitions Relating to Spectral Lines
      This page covers spectral lines in astrophysics, detailing residual intensity and flux, especially contrasting measurements from the sun and other stars. It defines equivalent width as a strength measure and explains true absorption and resonance scattering, highlighting their distinct effects on spectral lines. True absorption shares energy with gases, whereas scattering redirects photons without energy loss.
    • 13.3: Transfer of Line Radiation through the Atmosphere
      This page covers the methods for calculating stellar spectral lines using models like the Schuster-Schwarzschild and Milne-Eddington, highlighting their assumptions and complexities. It explains radiative transfer equations, focusing on the effects of absorption and scattering on residual flux and intensity.
    • 13.4: Problems
      This page discusses deriving and comparing residual intensity and flux expressions in atmospheric models through the Chandrasekhar two-stream approximation and nth-order methods. It examines Schuster-Schwarzschild and Milne-Eddington atmospheres, focusing on source function effects and optical depth. Key tasks include limb-darkening coefficient determination, assessing atmospheric responses to absorption/scattering lines, and applying model atmosphere codes for practical usage.
    • 13.5: Supplemental Reading
      This page highlights essential texts for grasping the radiative transfer equation, particularly within the Milne-Eddington model and spectral line formation. Key contributions include Aller (1963) on the Milne-Eddington model, Jefferies (1968) on the Schuster-Schwarzschild atmosphere, and Mihalas's classic works from 1970 and 1978, which provide an in-depth exploration of line transport theory, crucial for understanding stellar atmospheres and spectral line interactions.

    This page titled 13: Formation of Spectral Lines is shared under a Public Domain license and was authored, remixed, and/or curated by George W. Collins II (Pachart Foundation) via source content that was edited to the style and standards of the LibreTexts platform.