The millennium arecibo 21 centimeter absorption-line survey. I. Techniques and Gaussian fits

Carl Heiles; T. H. Troland

doi:10.1086/367785

The millennium arecibo 21 centimeter absorption-line survey. I. Techniques and Gaussian fits

Carl Heiles, T. H. Troland

Physics And Astronomy

Research output: Contribution to journal › Review article › peer-review

132 Scopus citations

Abstract

We review the theory of measuring spectral lines in emission/absorption observations and apply it to a new survey of the 21 cm line against 79 continuum sources. We develop an observing technique and least-squares procedure to determine the opacity profile, the expected emission profile, and their uncertainty profiles. We discuss the radiative transfer for the two-component interstellar H I gas and use Gaussian components, separate ones for the warm and cold neutral media (WNM and CNM), as a practical implementation of a simple but physically correct model that successfully treats both simple and complicated profiles. Our Gaussians provide CNM spin temperatures, upper limits on kinetic temperatures for both CNM and WNM from the line widths, column densities, and velocities; we discuss these astrophysical aspects in Paper II.

Original language	English
Pages (from-to)	329-354
Number of pages	26
Journal	Astrophysical Journal, Supplement Series
Volume	145
Issue number	2
DOIs	https://doi.org/10.1086/367785
State	Published - Apr 2003

Keywords

ISM: atoms
ISM: structure
Radio lines: ISM

ASJC Scopus subject areas

Astronomy and Astrophysics
Space and Planetary Science

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10.1086/367785

Cite this

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abstract = "We review the theory of measuring spectral lines in emission/absorption observations and apply it to a new survey of the 21 cm line against 79 continuum sources. We develop an observing technique and least-squares procedure to determine the opacity profile, the expected emission profile, and their uncertainty profiles. We discuss the radiative transfer for the two-component interstellar H I gas and use Gaussian components, separate ones for the warm and cold neutral media (WNM and CNM), as a practical implementation of a simple but physically correct model that successfully treats both simple and complicated profiles. Our Gaussians provide CNM spin temperatures, upper limits on kinetic temperatures for both CNM and WNM from the line widths, column densities, and velocities; we discuss these astrophysical aspects in Paper II.",

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AU - Troland, T. H.

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N2 - We review the theory of measuring spectral lines in emission/absorption observations and apply it to a new survey of the 21 cm line against 79 continuum sources. We develop an observing technique and least-squares procedure to determine the opacity profile, the expected emission profile, and their uncertainty profiles. We discuss the radiative transfer for the two-component interstellar H I gas and use Gaussian components, separate ones for the warm and cold neutral media (WNM and CNM), as a practical implementation of a simple but physically correct model that successfully treats both simple and complicated profiles. Our Gaussians provide CNM spin temperatures, upper limits on kinetic temperatures for both CNM and WNM from the line widths, column densities, and velocities; we discuss these astrophysical aspects in Paper II.

AB - We review the theory of measuring spectral lines in emission/absorption observations and apply it to a new survey of the 21 cm line against 79 continuum sources. We develop an observing technique and least-squares procedure to determine the opacity profile, the expected emission profile, and their uncertainty profiles. We discuss the radiative transfer for the two-component interstellar H I gas and use Gaussian components, separate ones for the warm and cold neutral media (WNM and CNM), as a practical implementation of a simple but physically correct model that successfully treats both simple and complicated profiles. Our Gaussians provide CNM spin temperatures, upper limits on kinetic temperatures for both CNM and WNM from the line widths, column densities, and velocities; we discuss these astrophysical aspects in Paper II.

KW - ISM: atoms

KW - ISM: structure

KW - Radio lines: ISM

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The millennium arecibo 21 centimeter absorption-line survey. I. Techniques and Gaussian fits

Abstract

Keywords

ASJC Scopus subject areas

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