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13.1: Introduction

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    Certainly the existence of such striking features as the dark spectral lines that break up the spectra of stars implies the presence of absorption processes that operate in a highly selective manner. The most obvious candidates for this selective absorption are the bound-bound atomic transitions occurring in the abundant species of common elements. Although we saw in Chapter 11 that bound-bound atomic transitions could, when they occur in very large numbers, depress large regions of the spectrum, some transitions will produce lines that dominate the nearby spectrum in a very singular manner. The contrast between these lines and the neighboring spectrum is often so marked that the investigator tends to make a distinction between a specific line and the neighboring spectrum by denoting the spectrum at nearby wavelengths as the "continuum" spectrum.

    This choice often causes some grief, for there is rarely a sharp transition between where the line absorption dominates the continuum absorption and vice versa. Indeed, the neighboring absorption of the continuum is often not even dominated by continuum processes, but represents an unresolved blend of discrete and continuous sources. Thus, the assumed location and the subsequent interpretation of the continuum are one of the largest sources of error in quantities resulting from the study of spectral lines. This problem, and the advent of relatively fast computing machines, has led modern analysis away from the discussion of single spectral lines to a synthesis of the entire spectrum by including all the relevant opacity sources. Although this approach undoubtedly yields more accurate results, it is difficult to appreciate the relative contribution of the various constituents of the atmosphere to the resultant spectrum.

    Therefore, we follow the traditional development and assume that a clear distinction can be made between the processes that produce a specific atomic spectral line and the absorption processes that control the spectrum at adjacent frequencies.

    This page titled 13.1: Introduction 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.