Book contents
- Frontmatter
- Contents
- Preface
- Conference participants
- Conference photograph / poster
- 1 Physics of H2 and HD
- 2 Formation - Destruction
- 3 Observations and Models
- 4 Extragalactic and Cosmology
- The Role of H2 Molecules in Cosmological Structure Formation
- The Role of H2 Molecules in Primordial Star Formation
- Evolution of Primordial H2 for Different Cosmological Models
- Dynamics of H2 Cool Fronts in the Primordial Gas
- Is Reionization Regulated by H2 in the Early Universe?
- H2 in Galaxies
- Transformation of Galaxies within the Hubble Sequence
- Extragalactic H2 and its Variable Relation to CO
- The Galactic Dark Matter Halo: Is it H2?
- Observations of H2 in Quasar Absorbers
- H2 Emission as a Diagnostic of Physical Processes in Starforming Galaxies
- 5 Outlook
- Author index
H2 in Galaxies
from 4 - Extragalactic and Cosmology
Published online by Cambridge University Press: 04 August 2010
- Frontmatter
- Contents
- Preface
- Conference participants
- Conference photograph / poster
- 1 Physics of H2 and HD
- 2 Formation - Destruction
- 3 Observations and Models
- 4 Extragalactic and Cosmology
- The Role of H2 Molecules in Cosmological Structure Formation
- The Role of H2 Molecules in Primordial Star Formation
- Evolution of Primordial H2 for Different Cosmological Models
- Dynamics of H2 Cool Fronts in the Primordial Gas
- Is Reionization Regulated by H2 in the Early Universe?
- H2 in Galaxies
- Transformation of Galaxies within the Hubble Sequence
- Extragalactic H2 and its Variable Relation to CO
- The Galactic Dark Matter Halo: Is it H2?
- Observations of H2 in Quasar Absorbers
- H2 Emission as a Diagnostic of Physical Processes in Starforming Galaxies
- 5 Outlook
- Author index
Summary
The bulk of the molecular gas in spiral galaxies is under the form of cold H2, that does not radiate and is only suspected through tracer molecules, such as CO. All tracers are biased, and in particular H2 could be highly underestimated in low metallicity regions. Our knowledge is reviewed of the H2 content of galaxies, according to their types, environment, or star-forming activities. The HI and CO components are generally well-mixed (spiral arms, vertical distribution), although their radial distributions are radically different, certainly due to radial abundance gradients. The hypothesis of H2 as dark matter is discussed, as well as the implications on galaxy dynamics, or the best perspectives for observational tests.
How to observe H2 in galaxies?
The bulk of molecular hydrogen in a galaxy is cold, around 10–20K, and therefore invisible. The first rotational level, accessible only through a quadrupolar transition, is more than 500 K above the fundamental. The presence of H2 is inferred essentially from the CO tracer. The carbon monoxide is the most abundant molecule after H2; its dipolemoment is small (0.1 Debye) and therefore CO is easily excited, the emission of CO(1–0) at 2.6mm (first level at 5.52K) is ubiquitous in the Galaxy.
The H2/CO conversion ratio
To calibrate the H2/CO ratio, the most direct and natural is to compare the UV absorption lines of CO and H2 along the same line of sight (Copernicus, e.g. Spitzer & Jenkins 1975; ORFEUS, cf Richter et al., this conference).
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- Information
- Molecular Hydrogen in Space , pp. 275 - 284Publisher: Cambridge University PressPrint publication year: 2000
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